Si4463-61-60-C High-Performance, Low-Current Transceiver

Si4463/61/60-C
H I G H - P ERFORMANCE , L O W -C U R R E N T T RANSCEIVER
Features
1






Remote keyless entry
Home automation
Industrial control
Sensor networks
Health monitors
Electronic shelf labels
XOUT
XIN
RXp 2
15 nSEL
RXn 3
14 SDI
GND
PAD
13 SDO
NC 5
12 SCLK
6
7
8
9
10 11 nIRQ
GPIO1
Smart metering (802.15.4g and WMBus)
Remote control
Home security and alarm
Telemetry
Garage and gate openers
GND
20 19 18 17 16
TX 4
Applications





SDN
GPIO0

Pin Assignments
GPIO2

VDD

GPIO3


Data rate = 100 bps to 1 Mbps
Fast wake and hop times
Power supply = 1.8 to 3.8 V
Excellent selectivity performance
69 dB adjacent channel
79 dB blocking at 1 MHz
Antenna diversity and T/R switch control
Highly configurable packet handler
TX and RX 64 byte FIFOs
129 bytes dedicated Tx or Rx
Auto frequency control (AFC)
Automatic gain control (AGC)
Low BOM
Low battery detector
Temperature sensor
20-Pin QFN package
IEEE 802.15.4g and WMBus compliant
Suitable for FCC Part 90 Mask D, FCC
part 15.247, 15,231, 15,249, ARIB T-108,
T-96, T-67, RCR STD-30, China
regulatory
ETSI Category I Operation EN300 220
TXRamp

Frequency range = 142–1050 MHz 
Receive sensitivity = –129 dBm

Modulation

(G)FSK, 4(G)FSK, (G)MSK

OOK
Max output power
+20 dBm (Si4463)

+16 dBm (Si4461)

+13 dBm (Si4460)

PA support for +27 or +30 dBm
Low active power consumption

10/13 mA RX

18 mA TX at +10 dBm (Si4460) 
Ultra low current powerdown modes
30 nA shutdown, 40 nA standby 
Preamble sense mode

6 mA average RX current at

1.2 kbps

10 µA average RX current at
50 kbps and 1 sec sleep interval
Fast preamble detection

1 byte preamble detection
VDD



Patents pending
Description
Silicon Laboratories' Si446x devices are high-performance, low-current
transceivers covering the sub-GHz frequency bands from 142 to 1050 MHz. The
radios are part of the EZRadioPRO® family, which includes a complete line of
transmitters, receivers, and transceivers covering a wide range of applications. All
parts offer outstanding sensitivity of –129 dBm while achieving extremely low
active and standby current consumption. The Si4463/61/60 offers frequency
coverage in all major bands. The Si446x includes optimal phase noise, blocking,
and selectivity performance for narrow band and wireless MBus licensed band
applications, such as FCC Part90 and 169 MHz wireless Mbus. The 69 dB
adjacent channel selectivity with 12.5 kHz channel spacing ensures robust
receive operation in harsh RF conditions, which is particularly important for narrow
band operation. The Si4463 offers exceptional output power of up to +20 dBm
with outstanding TX efficiency. The high output power and sensitivity results in an
industry-leading link budget of 146 dB allowing extended ranges and highly robust
communication links. The Si4460 active mode TX current consumption of 18 mA
at +10 dBm and RX current of 10 mA coupled with extremely low standby current
and fast wake times ensure extended battery life in the most demanding
applications. The Si4463 can achieve up to +27 dBm output power with built-in
ramping control of a low-cost external FET. The devices can meet worldwide
regulatory standards: FCC, ETSI, wireless MBus, and ARIB. All devices are
designed to be compliant with 802.15.4g and WMbus smart metering standards.
The devices are highly flexible and can be configured via the Wireless
Development Suite (WDS) available on the Silicon Labs website.
Rev 1.0 10/14
Copyright © 2014 by Silicon Laboratories
Si4463/61/60-C
Si4463/61/60-C
Functional Block Diagram
GPIO3 GPIO2
XIN XOUT
Loop
Filter
PFD / CP
VCO
FBDIV
TX DIV
SDN
RXN
TX
LO
Gen
Bootup
OSC
IF
PKDET
RF
PKDET
LNA
PA
PGA
ADC
nSEL
SDI
SDO
SCLK
nIRQ
LDOs
PowerRamp
Cntl
Digital
Logic
POR
LBD
32K LP
OSC
PA
LDO
TXRAMP
2
MODEM
FIFO
Packet
Handler
SPI Interface
Controller
RXP
30 MHz XO
Frac-N Div
VDD
GPIO0 GPIO1
Product
Freq. Range
Max Output
Power
TX Current at
Max Power and
868 MHz
Narrow Band
Support
IEEE 802.15.4g
PHY
Si4463
Major bands
142-1050 MHz
+20 dBm
85 mA


Si4461
Major bands
142-1050 MHz
+16 dBm
43 mA


Si4460
Major bands
142-1050 MHz
+13 dBm
24 mA


Rev 1.0
Si4463/61/60-C
TABLE O F C ONTENTS
Section
Page
1. Electrical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4
2. Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
3. Controller Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
3.1. Serial Peripheral Interface (SPI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
3.2. Fast Response Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18
3.3. Operating Modes and Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
3.4. Application Programming Interface (API) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
3.5. Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
3.6. GPIO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
4. Modulation and Hardware Configuration Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
4.1. Modulation Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
4.2. Hardware Configuration Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
4.3. Preamble Length . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
5. Internal Functional Blocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
5.1. RX Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
5.2. RX Modem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
5.3. Synthesizer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .31
5.4. Transmitter (TX) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .33
5.5. Crystal Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .36
6. Data Handling and Packet Handler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .38
6.1. RX and TX FIFOs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
6.2. Packet Handler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
7. RX Modem Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
8. Auxiliary Blocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
8.1. Wake-up Timer and 32 kHz Clock Source . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
8.2. Low Duty Cycle Mode (Auto RX Wake-Up) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .40
8.3. Temperature, Battery Voltage, and Auxiliary ADC . . . . . . . . . . . . . . . . . . . . . . . . . . 41
8.4. Low Battery Detector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .41
8.5. Antenna Diversity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
8.6. Preamble Sense Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
9. Wireless MBUS support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
10. ETSI EN300 220 Category 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
11. Pin Descriptions: Si4463/61/60 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
12. Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
13. Package Outline: Si4463/61/60 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
14. PCB Land Pattern: Si4463/61/60 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
15. Top Marking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .51
15.1. Si4463/61/60 Top Marking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
15.2. Top Marking Explanation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
Document Change List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .52
Contact Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .53
Rev 1.0
3
Si4463/61/60-C
1. Electrical Specifications
Table 1. DC Characteristics1
Parameter
Symbol
Supply Voltage
VDD
Range
Power Saving Modes IShutdown
IStandby
ISleepRC
ISleepXO
ISensor
-LBD
IReady
Preamble Sense
Mode Current
TUNE Mode Current
RX Mode Current
Ipsm
Ipsm
ITune_RX
ITune_TX
IRXH
IRXL
TX Mode Current
(Si4463)
TX Mode Current
(Si4460)
ITX_+20
ITX_+10
ITX_+10
ITX_+13
TX Mode Current
(Si4461)
ITX_+16
ITX_+13
Test Condition
Min
1.8
Typ
3.3
Max
3.8
Unit
V
RC Oscillator, Main Digital Regulator,
and Low Power Digital Regulator OFF
Register values maintained and RC
oscillator/WUT OFF
RC Oscillator/WUT ON and all register values maintained, and all other blocks OFF
Sleep current using an external 32 kHz crystal
Low battery detector ON, register values maintained,
and all other blocks OFF
Crystal Oscillator and Main Digital Regulator ON,
all other blocks OFF
Duty cycling during preamble search,
1.2 kbps, 4 byte preamble
Fixed 1 s wakeup interval, 50 kbps, 5 byte preamble
RX Tune, High Performance Mode
TX Tune, High Performance Mode
High Performance Mode
(measured at 915 MHz and 40 kbps data rate)
Low Power Mode
(measured at 315 MHz and 40 kbps data rate)
+20 dBm output power, Class-E match,
915 MHz, 3.3 V
+20 dBm output power, square-wave match,
169 MHz, 3.3 V
+13 dBm output power, Class-E match,
915 MHz, 3.3 V
+10 dBm output power, Class-E match,
915/868 MHz, 3.3 V2
+10 dBm output power, Class-E match,
169 MHz, 3.3 V2
+13 dBm output power, Class-E match,
915/868 MHz, 3.3 V
+16 dBm output power, class-E match,
868 MHz, 3.3 V
+13 dBm output power, switched-current match,
868 MHz, 3.3 V
—
30
1300
nA
—
40
2900
nA
—
740 3800
nA
—
—
1.7
1
—
—
µA
µA
—
1.8
—
mA
—
6
—
mA
—
—
—
—
10
7.6
7.8
13.7
—
—
—
22
µA
mA
mA
mA
—
10.9
—
mA
—
88
108
mA
—
68.5
80
mA
—
44.5
60
mA
—
19.7
—
mA
—
18
—
mA
—
24
—
mA
—
43
55
mA
—
33.5
40
mA
Notes:
1. All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage and
from –40 to +85 °C unless otherwise stated. All typical values apply at VDD = 3.3 V and 25 °C unless otherwise stated.
2. Measured on direct-tie RF evaluation board.
4
Rev 1.0
Si4463/61/60-C
Table 2. Synthesizer AC Electrical Characteristics
Parameter
Synthesizer Frequency
Range
Synthesizer Frequency
Resolution
Symbol
Test Condition
FSYN
Min
Typ
Max
Unit
850
—
1050
MHz
350
—
525
MHz
284
—
350
MHz
142
—
175
MHz
FRES-960
850–1050 MHz
—
28.6
—
Hz
FRES-525
420–525 MHz
—
14.3
—
Hz
FRES-420
350–420 MHz
—
11.4
—
Hz
FRES-350
283–350 MHz
—
9.5
—
Hz
FRES-175
142–175 MHz
—
4.7
—
Hz
Synthesizer Settling Time
tLOCK
Measured from exiting Ready mode with
XOSC running to any frequency.
Including VCO Calibration.
—
50
—
µs
Phase Noise
L(fM)
F = 10 kHz, 169 MHz, High Perf Mode
—
–117
–108 dBc/Hz
F = 100 kHz, 169 MHz, High Perf Mode
—
–120
–115 dBc/Hz
F = 1 MHz, 169 MHz, High Perf Mode
—
–138
–135 dBc/Hz
F = 10 MHz, 169 MHz, High Perf Mode
—
–148
–143 dBc/Hz
F = 10 kHz, 915 MHz, High Perf Mode
—
–102
–94
dBc/Hz
F = 100 kHz, 915 MHz, High Perf Mode
—
–105
–97
dBc/Hz
F = 1 MHz, 915 MHz, High Perf Mode
—
–125
–122 dBc/Hz
F = 10 MHz, 915 MHz, High Perf Mode
—
–138
–135 dBc/Hz
Note: All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage and
from –40 to +85 °C unless otherwise stated. All typical values apply at VDD = 3.3 V and 25 °C unless otherwise stated.
Rev 1.0
5
Si4463/61/60-C
Table 3. Receiver AC Electrical Characteristics1,2
Parameter
RX Frequency Range
RX Sensitivity 169 MHz3
Symbol
Test Condition
FRX
Min
Typ
Max
Unit
850
—
1050
MHz
350
—
525
MHz
284
—
350
MHz
142
—
175
MHz
PRX_0.5
(BER < 0.1%)
(500 bps, GFSK, BT = 0.5,
f = 250Hz)
—
–129
—
dBm
PRX_40
(BER < 0.1%)
(40 kbps, GFSK, BT = 0.5,
f = 20 kHz)
—
–110
–108
dBm
PRX_100
(BER < 0.1%)
(100 kbps, GFSK, BT = 0.5,
f = 50 kHz)
—
–106
–104
dBm
PRX_500
(BER < 0.1%)
(500 kbps, GFSK, BT = 0.5,
f = 250 kHz)
—
–98
–96
dBm
PRX_9.6
(PER 1%)
(9.6 kbps, 4GFSK, BT = 0.5,
f = ±2.4 kHz)
—
–110
—
dBm
PRX_1M
(PER 1%)
(1 Mbps, 4GFSK, BT = 0.5,
inner deviation = 83.3 kHz)
—
–89
—
dBm
PRX_OOK
(BER < 0.1%, 4.8 kbps, 350 kHz BW,
OOK, PN15 data)
—
–110
–107
dBm
(BER < 0.1%, 40 kbps, 350 kHz BW,
OOK, PN15 data)
—
–103
–100
dBm
(BER < 0.1%, 120 kbps, 350 kHz BW,
OOK, PN15 data)
—
–97
–93
dBm
Notes:
1. All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage and
from –40 to +85 °C unless otherwise stated. All typical values apply at VDD = 3.3 V and 25 °C unless otherwise stated.
2. For PER tests, 48 preamble symbols, 4 byte sync word, 10 byte payload and CRC-32 was used.
3. Measured over 50000 bits using PN9 data sequence and data and clock on GPIOs. Sensitivity is expected to be better
if reading data from packet handler FIFO especially at higher data rates.
6
Rev 1.0
Si4463/61/60-C
Table 3. Receiver AC Electrical Characteristics1,2 (Continued)
Parameter
RX Sensitivity
915/868 MHz3
RX Channel Bandwidth
Symbol
Test Condition
Min
Typ
Max
Unit
PRX_0.5
(BER < 0.1%)
(500 bps, GFSK, BT = 0.5,
f = 250Hz)
—
–127
—
dBm
PRX_40
(BER < 0.1%)
(40 kbps, GFSK, BT = 0.5,
f = 20 kHz)
—
–109
–107
dBm
PRX_100
(BER < 0.1%)
(100 kbps, GFSK, BT = 0.5,
f = 50 kHz)
—
–104
–102
dBm
PRX_500
(BER < 0.1%)
(500 kbps, GFSK, BT = 0.5,
f = 250 kHz)
—
–97
–92
dBm
PRX_9.6
(PER 1%)
(9.6 kbps, 4GFSK, BT = 0.5,
f =  kHz)
—
–109
—
dBm
PRX_1M
(PER 1%)
(1 Mbps, 4GFSK, BT = 0.5,
inner deviation = 83.3 kHz)
—
–88
—
dBm
PRX_OOK
(BER < 0.1%, 4.8 kbps, 350 kHz BW,
OOK, PN15 data)
—
–108
–104
dBm
(BER < 0.1%, 40 kbps, 350 kHz BW,
OOK, PN15 data)
—
–101
–97
dBm
(BER < 0.1%, 120 kbps, 350 kHz BW,
OOK, PN15 data)
—
–96
–91
dBm
1.1
—
850
kHz
BW
RESRSSI
Valid from –110 dBm to –90 dBm
—
±0.5
—
dB
1-Ch Offset Selectivity,
169 MHz3
C/I1-CH
—
–69
–59
dB
1-Ch Offset Selectivity,
450 MHz3
C/I1-CH
—
–60
–50
dB
1-Ch Offset Selectivity,
868 / 915 MHz3
C/I1-CH
Desired Ref Signal 3 dB above sensitivity, BER < 0.1%. Interferer is CW, and
desired is modulated with 2.4 kbps
F = 1.2 kHz GFSK with BT = 0.5, RX
channel BW = 4.8 kHz,
channel spacing = 12.5 kHz
—
–55
–45
dB
—
–79
–68
dB
—
–86
–75
dB
RSSI Resolution
Blocking 1 MHz Offset
1MBLOCK
Blocking 8 MHz Offset
8MBLOCK
Desired Ref Signal 3 dB above sensitivity, BER = 0.1%. Interferer is CW, and
desired is modulated with 2.4 kbps,
F = 1.2 kHz GFSK with BT = 0.5,
RX channel BW = 4.8 kHz
Notes:
1. All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage and
from –40 to +85 °C unless otherwise stated. All typical values apply at VDD = 3.3 V and 25 °C unless otherwise stated.
2. For PER tests, 48 preamble symbols, 4 byte sync word, 10 byte payload and CRC-32 was used.
3. Measured over 50000 bits using PN9 data sequence and data and clock on GPIOs. Sensitivity is expected to be better
if reading data from packet handler FIFO especially at higher data rates.
Rev 1.0
7
Si4463/61/60-C
Table 3. Receiver AC Electrical Characteristics1,2 (Continued)
Parameter
Image Rejection
(IF = 468.75 kHz)
Symbol
Test Condition
Min
Typ
Max
Unit
ImREJ
No image rejection calibration. Rejection at the image frequency.
RF = 460 MHz
30
40
—
dB
With image rejection calibration in
Si446x. Rejection at the image frequency. RF = 460 MHz
40
55
—
dB
No image rejection calibration. Rejection at the image frequency.
RF = 915 MHz
30
45
—
dB
With image rejection calibration in
Si446x. Rejection at the image frequency. RF = 915 MHz
40
52
—
dB
No image rejection calibration. Rejection at the image frequency.
RF = 169 MHz
35
45
—
dB
With image rejection calibration in
Si446x. Rejection at the image frequency. RF = 169 MHz
45
60
—
dB
Notes:
1. All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage and
from –40 to +85 °C unless otherwise stated. All typical values apply at VDD = 3.3 V and 25 °C unless otherwise stated.
2. For PER tests, 48 preamble symbols, 4 byte sync word, 10 byte payload and CRC-32 was used.
3. Measured over 50000 bits using PN9 data sequence and data and clock on GPIOs. Sensitivity is expected to be better
if reading data from packet handler FIFO especially at higher data rates.
8
Rev 1.0
Si4463/61/60-C
Table 4. Transmitter AC Electrical Characteristics
Parameter
TX Frequency
Range
Symbol
Test Condition
FTX
Min
Typ
Max
Unit
850
—
1050
MHz
350
—
525
MHz
284
—
350
MHz
142
—
175
MHz
(G)FSK Data Rate
DRFSK
0.1
—
500
kbps
4(G)FSK Data Rate
DR4FSK
0.2
—
1000
kbps
OOK Data Rate
DROOK
0.1
—
120
kbps
Modulation Deviation
Range
f960
850–1050 MHz
—
1.5
—
MHz
f525
420–525 MHz
—
750
—
kHz
f420
350–420 MHz
—
600
—
kHz
f350
283–350 MHz
—
500
—
kHz
f175
142–175 MHz
—
250
—
kHz
FRES-960
850–1050 MHz
—
28.6
—
Hz
FRES-525
420–525 MHz
—
14.3
—
Hz
FRES-420
350–420 MHz
—
11.4
—
Hz
FRES-350
283–350 MHz
—
9.5
—
Hz
FRES-175
142–175 MHz
—
4.7
—
Hz
Output Power Range
(Si4463)
PTX63
Typical range at 3.3 V with Class E
Match optimized for best PA efficiency
–20
—
+20
dBm
Output Power Range
(Si4461)
PTX61
Typical range at 3.3 V with Class E
Match optimized for best PA efficiency
–40
—
+16
dBm
PTX60
Typical range at 3.3 V with Class E
Match optimized for best PA efficiency.
Efficiency can be traded off for higher
Tx output power up to +13 dBm
–20
—
+12.5
dBm
Modulation Deviation
Resolution
Output Power Range
(Si4460)
Notes:
1. All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage and
from –40 to +85 °C unless otherwise stated. All typical values apply at VDD = 3.3 V and 25 °C unless otherwise stated.
2. The maximum data rate is dependent on the XTAL frequency and is calculated as per the formula: Maximum Symbol
Rate = Fxtal/60, where Fxtal is the XTAL frequency (typically 30 MHz).
3. Default API setting for modulation deviation resolution is double the typical value specified.
4. Output power is dependent on matching components and board layout.
Rev 1.0
9
Si4463/61/60-C
Table 4. Transmitter AC Electrical Characteristics (Continued)
Parameter
Test Condition
Min
Typ
Max
Unit
Output Power Variation
(Si4463)
At 20 dBm PA power setting, 915 MHz,
Class E match, 3.3 V, 25 °C
19
20
21
dBm
Output Power Variation
(Si4460)
At 10 dBm PA power setting, 915 MHz,
Class E match, 3.3 V, 25 °C
9
10
11
dBm
Output Power Variation
(Si4463)
At 20 dBm PA power setting, 169 MHz,
Square Wave match, 3.3 V, 25 °C
18.5
20
21
dBm
Output Power Variation
(Si4460)
At 10 dBm PA power setting, 169 MHz,
Square Wave match, 3.3 V, 25 °C
9.5
10
10.5
dBm
PRF_OUT
Using switched current match within
6 dB of max power using CLE match
within 6 dB of max power
—
0.25
0.4
dB
TX RF Output Level
Variation vs. Temperature
PRF_TEMP
–40 to +85 C
—
2.3
3
dB
TX RF Output Level
Variation vs. Frequency
PRF_FREQ
Measured across 902–928 MHz
—
0.6
1.7
dB
BT
Gaussian Filtering Bandwith Time
Product
—
0.5
—
TX RF Output Steps
Transmit Modulation
Filtering
Symbol
Notes:
1. All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage and
from –40 to +85 °C unless otherwise stated. All typical values apply at VDD = 3.3 V and 25 °C unless otherwise stated.
2. The maximum data rate is dependent on the XTAL frequency and is calculated as per the formula: Maximum Symbol
Rate = Fxtal/60, where Fxtal is the XTAL frequency (typically 30 MHz).
3. Default API setting for modulation deviation resolution is double the typical value specified.
4. Output power is dependent on matching components and board layout.
10
Rev 1.0
Si4463/61/60-C
Table 5. Auxiliary Block Specifications1
Parameter
Symbol
Test Condition
Min
Typ
Max
Unit
Temperature Sensor
Sensitivity
TSS
—
4.5
—
ADC
Codes/
°C
Low Battery Detector
Resolution
LBDRES
—
50
—
mV
Microcontroller Clock
Output Frequency Range2
Temperature Sensor
Conversion
XTAL Range3
30 MHz XTAL Start-Up Time
30 MHz XTAL Cap
Resolution
32 kHz XTAL Start-Up Time
32 kHz Accuracy using
Internal RC Oscillator
POR Reset Time
FMC
Configurable to Fxtal or Fxtal
divided by 2, 3, 7.5, 10, 15, or
30 where Fxtal is the reference
XTAL frequency. In addition,
32.768 kHz is also supported.
32.768K
—
Fxtal
Hz
TEMPCT
Programmable setting
—
3
—
ms
25
—
32
MHz
—
300
—
µs
30MRES
—
70
—
fF
t32k
—
2
—
sec
32KRCRES
—
2500
—
ppm
tPOR
—
—
6
ms
XTALRange
t30M
Start-up time will vary with
XTAL type and board layout.
Notes:
1. All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage and
from –45 to +85 °C unless otherwise stated. All typical values apply at Vdd=3.3V and 25C unless otherwise stated.
2. Microcontroller clock frequency tested in production at 1 MHz, 30 MHz, 32 MHz, and 32.768 kHz. Other frequencies
tested by bench characterization.
3. XTAL Range tested in production using an external clock source (similar to using a TCXO).
Rev 1.0
11
Si4463/61/60-C
Table 6. Digital IO Specifications (GPIO_x, SCLK, SDO, SDI, nSEL, nIRQ, SDN)1
Parameter
Rise Time
2,3
Fall Time3,4
Symbol
Test Condition
Min
Typ
Max
Unit
TRISE
0.1 x VDD to 0.9 x VDD,
CL = 10 pF,
DRV<1:0> = LL
—
2.3
—
ns
TFALL
0.9 x VDD to 0.1 x VDD,
CL = 10 pF,
DRV<1:0> = LL
—
2
—
ns
Input Capacitance
CIN
—
2
—
pF
Logic High Level Input Voltage
VIH
VDD x 0.7
—
—
V
Logic Low Level Input Voltage
VIL
—
—
VDD x 0.3
V
Input Current
IIN
0<VIN< VDD
–1
—
1
µA
Input Current If Pullup is Activated
IINP
VIL = 0 V
1
—
4
µA
LL3
—
6.66
—
mA
DRV[1:0] = LH
3
—
5.03
—
mA
IOmaxHL
DRV[1:0] = HL
3
—
3.16
—
mA
IOmaxHH
DRV[1:0] = HH3
—
1.13
—
mA
IOmaxLL
3
—
5.75
—
mA
3
—
4.37
—
mA
IOmaxHL
DRV[1:0] =
HL3
—
2.73
—
mA
IOmaxHH
DRV[1:0] = HH3
—
0.96
—
mA
IOmaxLL
3
—
2.53
—
mA
LH3
—
2.21
—
mA
IOmaxHL
DRV[1:0] = HL
3
—
1.70
—
mA
IOmaxHH
DRV[1:0] = HH3
—
0.80
—
mA
Logic High Level Output Voltage
VOH
DRV[1:0] = HL
VDD x 0.8
—
—
V
Logic Low Level Output Voltage
VOL
DRV[1:0] = HL
—
—
VDD x 0.2
V
Drive Strength for Output Low
Level
Drive Strength for Output High
Level
Drive Strength for Output High
Level for GPIO0
IOmaxLL
IOmaxLH
IOmaxLH
IOmaxLH
DRV[1:0] =
DRV[1:0] = LL
DRV[1:0] = LH
DRV[1:0] = LL
DRV[1:0] =
Notes:
1. All minimum and maximum values are guaranteed across the recommended operating conditions of supply voltage
and from –40 to +85 °C unless otherwise stated. All typical values apply at VDD = 3.3 V and 25 °C unless otherwise
stated.
2. 6.7 ns is typical for GPIO0 rise time.
3. Assuming VDD = 3.3 V, drive strength is specified at Voh (min) = 2.64 V and Vol(max) = 0.66 V at room temperature.
4. 2.4 ns is typical for GPIO0 fall time.
12
Rev 1.0
Si4463/61/60-C
Table 7. Thermal Characteristics
Parameter
Symbol
Value
Unit
Operating Ambient Temperature Range
TA
–40 to +85
°C
Thermal Impedance Junction to Ambient*
JA
25
°C/w
Tj
+105
°C
TSTG
–55 to +150
°C
Value
Unit
VDD to GND
–0.3, +3.8
V
Instantaneous VRF-peak to GND on TX Output Pin
–0.3, +8.0
V
Sustained VRF-peak to GND on TX Output Pin
–0.3, +6.5
V
–0.7, VDD + 0.3
V
+10
dBm
Junction Temperature Maximum Value*
Storage Temperature Range
*Note: JA and Tj are based on RF evaluation board measurements.
Table 8. Absolute Maximum Ratings
Parameter
Voltage on Analog Inputs
RX Input Power
Note: Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These
are stress ratings only and functional operation of the device at or beyond these ratings in the operational sections of
the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect
device reliability. Power Amplifier may be damaged if switched on without proper load or termination connected. TX
matching network design will influence TX VRF-peak on TX output pin. Caution: ESD sensitive device.
Rev 1.0
13
Si4463/61/60-C
2. Functional Description
The Si446x devices are high-performance, low-current, wireless ISM transceivers that cover the sub-GHz bands.
The wide operating voltage range of 1.8–3.8 V and low current consumption make the Si446x an ideal solution for
battery powered applications. The Si446x operates as a time division duplexing (TDD) transceiver where the
device alternately transmits and receives data packets. The device uses a single-conversion mixer to downconvert
the 2/4-level FSK/GFSK or OOK modulated receive signal to a low IF frequency. Following a programmable gain
amplifier (PGA) the signal is converted to the digital domain by a high performance  ADC allowing filtering,
demodulation, slicing, and packet handling to be performed in the built-in DSP increasing the receiver’s
performance and flexibility versus analog based architectures. The demodulated signal is output to the system
MCU through a programmable GPIO or via the standard SPI bus by reading the 64-byte RX FIFO.
A single high precision local oscillator (LO) is used for both transmit and receive modes since the transmitter and
receiver do not operate at the same time. The LO is generated by an integrated VCO and  Fractional-N PLL
synthesizer. The synthesizer is designed to support configurable data rates from 100 bps to 1 Mbps. The
Si4463/61/60 operate in the frequency bands of 142–175, 283–350, 350–525, and 850–1050 MHz with a
maximum frequency accuracy step size of 28.6 Hz. The transmit FSK data is modulated directly into the  data
stream and can be shaped by a Gaussian low-pass filter to reduce unwanted spectral content.
The Si4463 contains a power amplifier (PA) that supports output power up to +20 dBm with very high efficiency,
consuming only 70 mA at 169 MHz and 85 mA at 915 MHz. The integrated +20 dBm power amplifier can also be
used to compensate for the reduced performance of a lower cost, lower performance antenna or antenna with size
constraints due to a small form-factor. Competing solutions require large and expensive external PAs to achieve
comparable performance. The Si4461 supplies output power up to +16 dBm. The Si4460 is designed to support
single coin cell operation with current consumption below 18 mA for +10 dBm output power. Two match topologies
are available for the Si4461 and Si4460, class-E and switched-current. Class-E matching provides optimal current
consumption, while switched-current matching demonstrates the best performance over varying battery voltage
and temperature with slightly higher current consumption. The PA is single-ended to allow for easy antenna
matching and low BOM cost. The PA incorporates automatic ramp-up and ramp-down control to reduce unwanted
spectral spreading. The Si446x family supports frequency hopping, TX/RX switch control, and antenna diversity
switch control to extend the link range and improve performance. Built-in antenna diversity and support for
frequency hopping can be used to further extend range and enhance performance. Antenna diversity is completely
integrated into the Si446x and can improve the system link budget by 8–10 dB, resulting in substantial range
increases under adverse environmental conditions. A highly configurable packet handler allows for autonomous
encoding/decoding of nearly any packet structure. Additional system features, such as an automatic wake-up
timer, low battery detector, 64 byte TX/RX FIFOs, and preamble detection, reduce overall current consumption and
allows for the use of lower-cost system MCUs. An integrated temperature sensor, power-on-reset (POR), and
GPIOs further reduce overall system cost and size. The Si446x is designed to work with an MCU, crystal, and a
few passive components to create a very low-cost system.
The application shown in Figure 1 is designed for a system with a TX/RX direct-tie configuration without the use of
a TX/RX switch. Most applications with output power less than 17 dBm will use this configuration. Figure 2
demonstrates an application for +20 dBm using an external T/R-switch.
14
Rev 1.0
Si4463/61/60-C
RXn
XOUT
GND
14
Si4461
13
12
4
5
L1
7
6
8
11
10
9
nSEL
SDI
GP1
GP2
SDO
GP3
SCLK
GP4
nIRQ
GP5
GPIO1
NC
C1
C3
2
VDD
C4
C5
16
15
3
TX
17
GPIO0
L2
18
VDD
L3
L5
19
TXRAMP
L4
C2
RXp
1
Microcontroller
20
SDN
XIN
C6
GPIO2
GPIO3
30 MHz
VDD
C7
C8
C9
100 p
100 n
1u
Figure 1. Si4461 Direct-Tie Application Example
C4
TX
NC
C1
C3
C2
L1
XOUT
GND
XIN
16
15
2
14
Si4463
3
13
12
4
5
6
7
8
9
11
10
nSEL
SDI
GP1
GP2
SDO
GP3
SCLK
GP4
nIRQ
GP5
Microcontroller
C5
L2
17
GPIO1
L3
RXn
18
GPIO0
L4
RXp
L5
19
VDD
C6
20
1
TXRAMP
SDN
VDD
C7
GPIO2
GPIO3
30 MHz
VDD
Figure 2. Si4463 Single Antenna with RF Switch Example
Rev 1.0
15
Si4463/61/60-C
3. Controller Interface
3.1. Serial Peripheral Interface (SPI)
The Si446x communicates with the host MCU over a standard 4-wire serial peripheral interface (SPI): SCLK, SDI,
SDO, and nSEL. The SPI interface is designed to operate at a maximum of 10 MHz. The SPI timing parameters
are demonstrated in Table 9. The host MCU writes data over the SDI pin and can read data from the device on the
SDO output pin. Figure 3 demonstrates an SPI write command. The nSEL pin should go low to initiate the SPI
command. The first byte of SDI data will be one of the firmware commands followed by n bytes of parameter data
which will be variable depending on the specific command. The rising edges of SCLK should be aligned with the
center of the SDI data.
Table 9. Serial Interface Timing Parameters
Symbol
Parameter
Min
(ns)
Max
(ns)
tCH
Clock high time
40
tCL
Clock low time
40
tDS
Data setup time
20
tDH
Data hold time
20
tDD
Output data delay time
43
tDE
Output disable time
45
tSS
Select setup time
20
tSH
Select hold time
50
tSW
Select high period
80
Diagram
SCLK
tSS
tCL
tCH
tDS
tDH
tDD
tSH tDE
SDI
SDO
tSW
nSEL
*Note: CL = 10 pF; VDD = 1.8 V; SDO Drive strength setting = 10.
nSEL
SDO
SDI
FW Command
Param Byte 0
Param Byte n
SCLK
Figure 3. SPI Write Command
The Si446x contains an internal MCU which controls all the internal functions of the radio. For SPI read commands
a typical MCU flow of checking clear-to-send (CTS) is used to make sure the internal MCU has executed the
command and prepared the data to be output over the SDO pin. Figure 4 demonstrates the general flow of an SPI
read command. Once the CTS value reads FFh then the read data is ready to be clocked out to the host MCU. The
typical time for a valid FFh CTS reading is 20 µs. Figure 5 demonstrates the remaining read cycle after CTS is set
to FFh. The internal MCU will clock out the SDO data on the negative edge so the host MCU should process the
SDO data on the rising edge of SCLK.
16
Rev 1.0
Si4463/61/60-C
Firmware Flow
0xFF
Send Command
Read CTS
CTS Value
Retrieve
Response
0x00
NSEL
CTS
SDO
SDI
ReadCmdBuff
SCK
Figure 4. SPI Read Command—Check CTS Value
NSEL
SDO
Response Byte 0
Response Byte n
SDI
SCK
Figure 5. SPI Read Command—Clock Out Read Data
Rev 1.0
17
Si4463/61/60-C
3.2. Fast Response Registers
The fast response registers are registers that can be read immediately without the requirement to monitor and
check CTS. There are four fast response registers that can be programmed for a specific function. The fast
response registers can be read through API commands, 0x50 for Fast Response A, 0x51 for Fast Response B,
0x53 for Fast Response C, and 0x57 for Fast Response D. The fast response registers can be configured by the
“FRR_CTL_X_MODE” properties.
The fast response registers may be read in a burst fashion. After the initial 16 clock cycles, each additional eight
clock cycles will clock out the contents of the next fast response register in a circular fashion. The value of the
FRRs will not be updated unless NSEL is toggled.
3.3. Operating Modes and Timing
The primary states of the Si446x are shown in Figure 6. The shutdown state completely shuts down the radio to
minimize current consumption. Standby/Sleep, SPI Active, Ready, TX Tune, and RX tune are available to optimize
the current consumption and response time to RX/TX for a given application. API commands START_RX,
START_TX, and CHANGE_STATE control the operating state with the exception of shutdown which is controlled
by SDN, pin 1. Table 10 shows each of the operating modes with the time required to reach either RX or TX mode
as well as the current consumption of each mode. The times in Table 9 are measured from the rising edge of nSEL
until the chip is in the desired state. Note that these times are indicative of state transition timing but are not
guaranteed and should only be used as a reference data point. An automatic sequencer will put the chip into RX or
TX from any state. It is not necessary to manually step through the states. To simplify the diagram it is not shown
but any of the lower power states can be returned to automatically after RX or TX.
Figure 6. State Machine Diagram
18
Rev 1.0
Si4463/61/60-C
Table 10. Operating State Response Time and Current Consumption
Response Time to
TX
RX
Current in State
/Mode
Shutdown State
15 ms
15 ms
30 nA
Standby State
Sleep State
SPI Active State
Ready State
TX Tune State
RX Tune State
440 µs
440 µs
340 µs
100 µs
58 µs
—
440 µs
440 µs
340 µs
100 µs
—
60 µs
40 nA
740 nA
1.35 mA
1.8 mA
7.8 mA
7.6 mA
TX State
—
100 µs
18 mA @ +10 dBm
RX State
100 µs
75 µs
10.9 or 13.7 mA
State/Mode
Note: TXRX and RXTX state transition timing can be reduced to 70 µs if using Zero-IF mode.
Figure 7 shows the POR timing and voltage requirements. The power consumption (battery life) depends on the
duty cycle of the application or how often the part is in either Rx or Tx state. In most applications the utilization of
the standby state will be most advantageous for battery life but for very low duty cycle applications shutdown will
have an advantage. For the fastest timing the next state can be selected in the START_RX or START_TX API
commands to minimize SPI transactions and internal MCU processing.
3.3.1. Power on Reset (POR)
A Power On Reset (POR) sequence is used to boot the device up from a fully off or shutdown state. To execute this
process, VDD must ramp within 1ms and must remain applied to the device for at least 10 ms. If VDD is removed,
then it must stay below 0.15 V for at least 10 ms before being applied again. See Figure 7 and Table 11 for details.
VDD
VR RH
VR RL
Time
tSR
tPORH
Figure 7. POR Timing Diagram
Rev 1.0
19
Si4463/61/60-C
Table 11. POR Timing
Variable
tPORH
Description
High time for VDD to fully settle POR circuit
tPORL
Low time for VDD to enable POR
VRRH
Voltage for successful POR
VRRL
Starting Voltage for successful POR
tSR
Min
Typ
Max
Units
10
ms
10
ms
90% x Vdd
V
0
Slew rate of VDD for successful POR
150
mV
1
ms
3.3.2. Shutdown State
The shutdown state is the lowest current consumption state of the device with nominally less than 30 nA of current
consumption. The shutdown state may be entered by driving the SDN pin (Pin 1) high. The SDN pin should be held
low in all states except the shutdown state. In the shutdown state, the contents of the registers are lost and there is
no SPI access. When coming out of the shutdown state a power on reset (POR) will be initiated along with the
internal calibrations. After the POR the POWER_UP command is required to initialize the radio. The SDN pin
needs to be held high for at least 10us before driving low again so that internal capacitors can discharge. Not
holding the SDN high for this period of time may cause the POR to be missed and the device to boot up incorrectly.
If POR timing and voltage requirements cannot be met, it is highly recommended that SDN be controlled using the
host processor rather than tying it to GND on the board.
3.3.3. Standby State
Standby state has the lowest current consumption with the exception of shutdown but has much faster response
time to RX or TX mode. In most cases standby should be used as the low power state. In this state the register
values are maintained with all other blocks disabled. The SPI is accessible during this mode but any SPI event,
including FIFO R/W, will enable an internal boot oscillator and automatically move the part to SPI active state. After
an SPI event the host will need to re-command the device back to standby through the “Change State” API
command to achieve the 40 nA current consumption. If an interrupt has occurred (i.e., the nIRQ pin = 0) the
interrupt registers must be read to achieve the minimum current consumption of this mode.
3.3.4. Sleep State
Sleep state is the same as standby state but the wake-up-timer and a 32 kHz clock source are enabled. The
source of the 32 kHz clock can either be an internal 32 kHz RC oscillator which is periodically calibrated or a
32 kHz oscillator using an external XTAL.The SPI is accessible during this mode but an SPI event will enable an
internal boot oscillator and automatically move the part to SPI active mode. After an SPI event the host will need to
re-command the device back to sleep. If an interrupt has occurred (i.e., the nIRQ pin = 0) the interrupt registers
must be read to achieve the minimum current consumption of this mode.
3.3.5. SPI Active State
In SPI active state the SPI and a boot up oscillator are enabled. After SPI transactions during either standby or
sleep the device will not automatically return to these states. A “Change State” API command will be required to
return to either the standby or sleep modes.
3.3.6. Ready State
Ready state is designed to give a fast transition time to TX or RX state with reasonable current consumption. In this
mode the Crystal oscillator remains enabled reducing the time required to switch to TX or RX mode by eliminating
the crystal start-up time.
3.3.7. TX State
The TX state may be entered from any of the state with the “Start TX” or “Change State” API commands. A built-in
sequencer takes care of all the actions required to transition between states from enabling the crystal oscillator to
ramping up the PA. The following sequence of events will occur automatically when going from standby to TX state.
1. Enable internal LDOs.
2. Start up crystal oscillator and wait until ready (controlled by an internal timer).
20
Rev 1.0
Si4463/61/60-C
3. Enable PLL.
4. Calibrate VCO/PLL.
5. Wait until PLL settles to required transmit frequency (controlled by an internal timer).
6. Activate power amplifier and wait until power ramping is completed (controlled by an internal timer).
7. Transmit packet.
Steps in this sequence may be eliminated depending on which state the chip is configured to prior to commanding
to TX. By default, the VCO and PLL are calibrated every time the PLL is enabled. When the START_TX API
command is utilized the next state may be defined to ensure optimal timing and turnaround.
Figure 8 shows an example of the commands and timing for the START_TX command. CTS will go high as soon
as the sequencer puts the part into TX state. As the sequencer is stepping through the events listed above, CTS
will be low and no new commands or property changes are allowed. If the Fast Response (FRR) or nIRQ is used to
monitor the current state there will be slight delay caused by the internal hardware from when the event actually
occurs to when the transition occurs on the FRR or nIRQ. The time from entering TX state to when the FRR will
update is 5 µs and the time to when the nIRQ will transition is 13 µs. If a GPIO is programmed for TX state or used
as control for a transmit/receive switch (TR switch) there is no delay.
CTS
NSEL
SDI
START_TX
Current State
FRR
YYY State
Tx State
YYY State
TXCOMPLETE_STATE
Tx State
TXCOMPLETE_STATE
nIRQ
GPIOx – TX state
Figure 8. Start_TX Commands and Timing
3.3.8. RX State
The RX state may be entered from any of the other states by using the “Start RX” or “Change State” API command.
A built-in sequencer takes care of all the actions required to transition between states. The following sequence of
events will occur automatically to get the chip into RX mode when going from standby to RX state:
1. Enable the digital LDO and the analog LDOs.
2. Start up crystal oscillator and wait until ready (controlled by an internal timer).
3. Enable PLL.
4. Calibrate VCO
5. Wait until PLL settles to required receive frequency (controlled by an internal timer).
6. Enable receiver circuits: LNA, mixers, and ADC.
7. Enable receive mode in the digital modem.
Depending on the configuration of the radio, all or some of the following functions will be performed automatically
by the digital modem: AGC, AFC (optional), update status registers, bit synchronization, packet handling (optional)
including sync word, header check, and CRC. Similar to the TX state, the next state after RX may be defined in the
“Start RX” API command. The START_RX commands and timing will be equivalent to the timing shown in Figure 8.
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3.4. Application Programming Interface (API)
An application programming interface (API), which the host MCU will communicate with, is embedded inside the
device. The API is divided into two sections, commands and properties. The commands are used to control the
chip and retrieve its status. The properties are general configurations which will change infrequently. The API
descriptions can be found on the Silicon Labs website.
3.5. Interrupts
The Si446x is capable of generating an interrupt signal when certain events occur. The chip notifies the
microcontroller that an interrupt event has occurred by setting the nIRQ output pin LOW = 0. This interrupt signal
will be generated when any one (or more) of the interrupt events (corresponding to the Interrupt Status bits) occur.
The nIRQ pin will remain low until the microcontroller reads the Interrupt Status Registers. The nIRQ output signal
will then be reset until the next change in status is detected.
The interrupts sources are grouped into three groups: packet handler, chip status, and modem. The individual
interrupts in these groups can be enabled/disabled in the interrupt property registers. An interrupt must be enabled
for it to trigger an event on the nIRQ pin. The interrupt group must be enabled as well as the individual interrupts in
API properties described in the API documentation.
Once an interrupt event occurs and the nIRQ pin is low there are two ways to read and clear the interrupts. All of
the interrupts may be read and cleared in the “GET_INT_STATUS” API command. By default all interrupts will be
cleared once read. If only specific interrupts want to be read in the fastest possible method the individual interrupt
groups (Packet Handler, Chip Status, Modem) may be read and cleared by the “GET_MODEM_STATUS”,
“GET_PH_STATUS” (packet handler), and “GET_CHIP_STATUS” API commands.
The instantaneous status of a specific function maybe read if the specific interrupt is enabled or disabled. The
status results are provided after the interrupts and can be read with the same commands as the interrupts. The
status bits will give the current state of the function whether the interrupt is enabled or not.
The fast response registers can also give information about the interrupt groups but reading the fast response
registers will not clear the interrupt and reset the nIRQ pin.
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3.6. GPIO
Four general purpose IO pins are available to utilize in the application. The GPIO are configured by the
GPIO_PIN_CFG command in address 13h. For a complete list of the GPIO options please see the API guide.
GPIO pins 0 and 1 should be used for active signals such as data or clock. GPIO pins 2 and 3 have more
susceptibility to generating spurious in the synthesizer than pins 0 and 1. The drive strength of the GPIOs can be
adjusted with the GEN_CONFIG parameter in the GPIO_PIN_CFG command. By default the drive strength is set
to minimum. The default configuration for the GPIOs and the state during SDN is shown below in Table 12.The
state of the IO during shutdown is also shown inTable 12. As indicated previously in Table 6, GPIO 0 has lower
drive strength than the other GPIOs.
Table 12. GPIOs
Pin
SDN State
POR Default
GPIO0
0
POR
GPIO1
0
CTS
GPIO2
0
POR
GPIO3
0
POR
nIRQ
resistive VDD pull-up
nIRQ
SDO
resistive VDD pull-up
SDO
SDI
High Z
SDI
SCLK
High Z
SCLK
NSEL
High Z
NSEL
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4. Modulation and Hardware Configuration Options
The Si446x supports different modulation options and can be used in various configurations to tailor the device to
any specific application or legacy system for drop in replacement. The modulation and configuration options are set
in API property, MODEM_MOD_TYPE. Refer to the API documentation for details on modem related properties.
4.1. Modulation Types
The Si446x supports five different modulation options: Gaussian frequency shift keying (GFSK), frequency-shift
keying (FSK), four-level GFSK (4GFSK), four-level FSK (4FSK), and on-off keying (OOK). Minimum shift keying
(MSK) can also be created by using GFSK with the appropriate modulation index (h = 0.5). GFSK is the
recommended modulation type as it provides the best performance and cleanest modulation spectrum. The
modulation type is set by the “MOD_TYPE[2:0]” field in the “MODEM_MOD_TYPE” API property. A
continuous-wave (CW) carrier may also be selected for RF evaluation purposes. The modulation source may also
be selected to be a pseudo-random source for evaluation purposes.
4.2. Hardware Configuration Options
There are different receive demodulator options to optimize the performance and mutually-exclusive options for
how the RX/TX data is transferred from the host MCU to the RF device.
4.2.1. Receive Demodulator Options
There are multiple demodulators integrated into the device to optimize the performance for different applications,
modulation formats, and packet structures. The calculator built into WDS will choose the optimal demodulator
based on the input criteria.
4.2.1.1. Synchronous Demodulator
The synchronous demodulator's internal frequency error estimator acquires the frequency error based on a
101010 preamble structure. The bit clock recovery circuit locks to the incoming data stream within four transactions
of a “10” or “01” bit stream. The synchronous demodulator gives optimal performance for 2- or 4-level (G)FSK
modulation that has a modulation index less than 2.
4.2.1.2. Asynchronous Demodulator
The asynchronous demodulator should be used for OOK modulation and for (G)FSK modulation under one or
more of the following conditions:
Modulation
index > 2
preamble (not 1010101... pattern)
When the modulation index exceeds 2, the asynchronous demodulator has better sensitivity compared to the
synchronous demodulator. An internal deglitch circuit provides a glitch-free data output and a data clock signal to
simplify the interface to the host. There is no requirement to perform deglitching in the host MCU. The
asynchronous demodulator will typically be utilized for legacy systems and will have many performance benefits
over devices used in legacy designs. Unlike the Si4432/31 solution for non-standard packet structures, there is no
requirement to perform deglitching on the data in the host MCU. Glitch-free data is output from Si446x devices, and
a sample clock for the asynchronous data can also be supplied to the host MCU; so, oversampling or bit clock
recovery is not required by the host MCU. There are multiple detector options in the asynchronous demodulator
block, which will be selected based upon the options entered into the WDS calculator. The asynchronous
demodulator's internal frequency error estimator is able to acquire the frequency error based on any preamble
structure.
Non-standard
4.2.2. RX/TX Data Interface With MCU
There are two different options for transferring the data from the RF device to the host MCU. FIFO mode uses the
SPI interface to transfer the data, while direct mode transfers the data in real time over a GPIO pin.
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4.2.2.1. FIFO Mode
In FIFO mode, the transmit and receive data is stored in integrated FIFO register memory. The TX FIFO is
accessed by writing command 66h followed directly by the data/clk that the host wants to write into the TX FIFO.
The RX FIFO is accessed by writing command 77h followed by the number of clock cycles of data the host would
like to read out of the RX FIFO. The RX data will be clocked out onto the SDO pin.
In TX FIFO mode, the data bytes stored in FIFO memory are “packaged” together with other fields and bytes of
information to construct the final transmit packet structure. These other potential fields include the Preamble, Sync
word, and CRC checksum. In TX mode, the packet structure may be highly customized by enabling or disabling
individual fields; for example, it is possible to disable both the Preamble and Sync Word fields and to load the entire
packet structure into FIFO memory. For further information on the configuration of the FIFOs for a specific
application or packet size, see "6. Data Handling and Packet Handler" on page 38. In RX mode, the Packet
Handler must be enabled to allow storage of received data bytes into RX FIFO memory. The Packet Handler is
required to detect the Sync Word, and proper detection of the Sync Word is required to determine the start of the
Payload. All bytes after the Sync Word are stored in RX FIFO memory except the CRC checksum and (optionally)
the variable packet length byte(s). When the FIFO is being used in RX mode, all of the received data may still be
observed directly (in realtime) by properly programming a GPIO pin as the RXDATA output pin; this can be quite
useful during application development. When in FIFO mode, the chip will automatically exit the TX or RX State
when either the PACKET_SENT or PACKET_RX interrupt occurs. The chip will return to the state programmed in
the argument of the “START TX” or “START RX” API command, TXCOMPLETE_STATE[3:0] or
RXVALID_STATE[3:0]. For example, the chip may be placed into READY mode after a TX packet by sending the
“START TX” command and by writing 30h to the TXCOMPLETE_STATE[3:0] argument. The chip will transmit all of
the contents of the FIFO, and the PACKET_SENT interrupt will occur. When this event occurs, the chip will return
to the READY state as defined by TXCOMPLETE_STATE[3:0] = 30h.
4.2.2.2. FIFO Direct Mode (Infinite Receive)
In some applications, there is a need to receive extremely long packets (greater than 40 kB) while relying on
preamble and sync word detection from the on-chip packet handler. In these cases, the packet length is unknown,
and the device will load the bits after the sync word into the RX FIFO forever. Other features, such as Data
Whitening, CRC, Manchester, etc., are supported in this mode, but CRC calculation is not because the end of
packet is unknown to the device. The RX data and clock are also available on GPIO pins. The host MCU will need
to reset the packet handler by issuing a START_RX to begin searching for a new packet.
4.2.2.3. Automatic TX Packet Repeat
In TX mode, there is an option to send the FIFO contents repeatedly with a user-defined number of times to repeat.
This is limited to the FIFO size, and the entire contents of the packet including preamble and sync word need to be
loaded into the TX FIFO. This is selectable via the START_TX API, and packets will be sent without any gaps
between them.
4.2.2.4. Direct Mode
For legacy systems that perform packet handling within the host MCU or other baseband chip, it may not be
desirable to use the FIFO. For this scenario, a Direct mode is provided, which bypasses the FIFOs entirely. In TX
Direct mode, the TX modulation data is applied to an input pin of the chip and processed in “real time” (i.e., not
stored in a register for transmission at a later time). Any of the GPIOs may be configured for use as the TX Data
input function. Furthermore, an additional pin may be required for a TX Clock output function if GFSK modulation is
desired (only the TX Data input pin is required for FSK or OOK). To achieve direct mode, the desired GPIO pin
must be configured as a digital input by setting the GPIO_PIN_CFG API command = enumeration 0x04 in addition
to setting the MODEM_MOD_TYPE API property to source the TXDATA stream from that same GPIO pin. For
GFSK, “TX_DIRECT_MODE_TYPE” must be set to synchronous. For 2FSK or OOK, the type can be set to
asynchronous or synchronous. The MOD_SOURCE[1:0] field within the MODEM_MOD_TYPE property should be
set = 0x01h for all Direct mode configurations. In RX Direct mode, the RX Data and RX Clock can be programmed
for direct (real-time) output to GPIO pins. The microcontroller may then process the RX data without using the
FIFO or packet handler functions of the RFIC.
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4.3. Preamble Length
4.3.1. Digital Signal Arrival Detector (DSA)
Traditional preamble detection requires 20 bits to detect preamble. This device introduces a new approach to
signal detection that can detect a preamble pattern in as little as one byte. If AFC is enabled, a preamble length of
two bytes is sufficient to reliably detect signal arrival and settle a one-shot AFC. The impact of this is significant for
low-power solutions as it reduces the amount of time the receiver has to stay active to detect the preamble. This
feature is used with Preamble Sense Mode (see "8.6. Preamble Sense Mode" on page 42) and the latest WMBus
N modes as well as with features, such as frequency hopping, which may use signal arrival as a condition to hop.
The traditional preamble detector is also available to maintain backward compatibility. Note that the DSA is using
the RSSI jump detector. When used for collision detection, the RSSI jump detector may need to be reconfigured
after preamble detection. Refer to the API documentation for details on how to configure the device to use the
signal arrival detector.
4.3.2. Traditional Preamble Detection
Optimal performance of the chip is obtained by qualifying reception of a valid Preamble pattern prior to continuing
with reception of the remainder of the packet (e.g., Sync Word and Payload). Reception of the Preamble is
considered valid when a minimum number of consecutive bits of 101010... pattern have been received; the
required threshold for preamble detection is specified by the RX_THRESH[6:0] field in the
PREAMBLE_CONFIG_STD_1 property. The appropriate value of the detection threshold depends upon the
system application and typically trades off speed of acquisition against the probability of false detection. If the
detection threshold is set too low, the chip may readily detect the short pattern within noise; the chip then proceeds
to attempt to detect the remainder of the non-existent packet, with the result that the arrival of an actual valid
packet may be missed. If the detection threshold is set too high, the required number of transmitted Preamble bits
must be increased accordingly, leading to longer packet lengths and shorter battery life. A preamble detection
threshold value of 20 bits is suitable for most applications. The total length of the transmitted Preamble field must
be at least equal to the receive preamble detection threshold, plus an additional number of bits to allow for
acquisition of bit timing and settling of the AFC algorithm. The recommended preamble detection thresholds and
preamble lengths for a variety of operational modes are listed in Table 13.
Configuration of the preamble detection threshold in the RX_THRESH[6:0] field is only required for reception of a
standard Preamble pattern (i.e., 101010... pattern). Reception of a repetitive but non-standard Preamble pattern is
also supported in the chip but is configured through the PREAMBLE_CONFIG_NSTD and PREAMBLE_PATTERN
properties.
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Table 13. Recommended Preamble Length
Mode
AFC
Antenna
Diversity
Preamble Type
Recommended
Preamble Length
Recommended
Preamble Detection
Threshold
(G)FSK
Disabled
Disabled
Standard
4 Bytes
20 bits
(G)FSK
Enabled
Disabled
Standard
5 Bytes
20 bits
(G)FSK
Disabled
Disabled
Non-standard
2 Bytes
0 bits
(G)FSK
Enabled
(G)FSK
Disabled
Enabled
Standard
7 Bytes
24 bits
(G)FSK
Enabled
Enabled
Standard
8 Bytes
24 bits
4(G)FSK
Disabled
Disabled
Standard
40 symbols
16 symbols
4(G)FSK
Enabled
Disabled
Standard
48 symbols
16 symbols
Non-standard
4(G)FSK
Not Supported
Non-standard
Not Supported
OOK
Disabled
Disabled
Standard
4 Bytes
20 bits
OOK
Disabled
Disabled
Non-standard
2 Bytes
0 bits
OOK
Enabled
Not Supported
Notes:
1. The recommended preamble length and preamble detection thresholds listed above are to achieve 0% PER. They may
be shortened when occasional packet errors are tolerable.
2. All recommended preamble lengths and detection thresholds include AGC and BCR settling times.
3. “Standard” preamble type should be set for an alternating data sequence at the max data rate (…10101010…)
4. “Non-standard” preamble type can be set for any preamble type including …10101010...
5. When preamble detection threshold = 0, sync word needs to be 3 Bytes to avoid false syncs. When only a 2 Byte sync
word is available the sync word detection can be extended by including the last preamble Byte into the RX sync word
setting.
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5. Internal Functional Blocks
The following sections provide an overview to the key internal blocks and features.
5.1. RX Chain
The internal low-noise amplifier (LNA) is designed to be a wide-band LNA that can be matched with three or four
external discrete components to cover any common range of frequencies in the sub-GHz band. The LNA has
extremely low noise to suppress the noise of the following stages and achieve optimal sensitivity; so, no external
gain or front-end modules are necessary. The LNA has gain control, which is controlled by the internal automatic
gain control (AGC) algorithm. The LNA is followed by an I-Q mixer, filter, programmable gain amplifier (PGA), and
ADC. The I-Q mixers downconvert the signal to an intermediate frequency. The PGA then boosts the gain to be
within dynamic range of the ADC. The ADC rejects out-of-band blockers and converts the signal to the digital
domain where filtering, demodulation, and processing is performed. Peak detectors are integrated at the output of
the LNA and PGA for use in the AGC algorithm.
The RX and TX pins may be directly tied externally for output powers less than +17 dBm in the higher-frequency
bands and can support +20 dBm in the lower bands, such as 169MHz. This reduces BOM cost by saving the
expense of a switch for single antenna solutions. See the direct-tie reference designs on the Silicon Labs web site
for more details.
5.1.1. RX Chain Architecture
It is possible to operate the RX chain in different architecture configurations: fixed-IF, zero-IF, and scaled-IF. There
are trade-offs between the architectures in terms of sensitivity, selectivity, and image rejection. Fixed-IF is the default
configuration and is recommended for most applications. With 35 dB native image rejection and autonomous image
calibration to achieve 55 dB, the fixed-IF solution gives the best performance for most applications. Fixed-IF obtains
the best sensitivity, but it has the effect of degraded selectivity at the image frequency. An autonomous image
rejection calibration is included in Si446x devices and described in more detail in "5.2.3. Image Rejection and
Calibration" on page 30. For scaled-IF and zero-IF, the sensitivity is degraded for data rates less than 100 kbps or
bandwidths less than 200 kHz. The reduction in sensitivity is caused by increased flicker noise as dc is approached.
The benefit of zero-IF is that there is no image frequency; so, there is no degradation in the selectivity curve, but it
has the worst sensitivity. Scaled-IF is a trade-off between fixed-IF and zero-IF. In the scaled-IF architecture, the
image frequency is placed or hidden in the adjacent channel where it only slightly degrades the typical adjacent
channel selectivity. The scaled-IF approach has better sensitivity than zero-IF but still some degradation in
selectivity due to the image. In scaled-IF mode, the image frequency is directly proportional to the channel
bandwidth selected. Figure 9 demonstrates the trade-off in sensitivity between the different architecture options.
1% PER sensitivity vs. data rate (h=1)
-95
Sensitivity (dBm)
-100
-105
Fixed IF
Scaled IF
-110
Zero IF
-115
-120
1
10
100
Data rate (kbps)
Figure 9. RX Architecture vs. Data Rate
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5.2. RX Modem
Using high-performance ADCs allows channel filtering, image rejection, and demodulation to be performed in the
digital domain, which allows for flexibility in optimizing the device for particular applications. The digital modem
performs the following functions:
Channel
selection filter
TX modulation
RX demodulation
Automatic Gain Control (AGC)
Preamble detection
Invalid preamble detection
Radio signal strength indicator (RSSI)
Automatic frequency compensation (AFC)
Image Rejection Calibration
Packet handling
Cyclic redundancy check (CRC)
The digital channel filter and demodulator are optimized for ultra-low-power consumption and are highly
configurable. Supported modulation types are GFSK, FSK, 4GFSK, 4FSK, GMSK, and OOK. The channel filter
can be configured to support bandwidths ranging from 850 kHz down to 1.1 kHz. A large variety of data rates are
supported ranging from 100 bps up to 1 Mbps. The configurable preamble detector is used with the synchronous
demodulator to improve the reliability of the sync-word detection. Preamble detection can be skipped using only
sync detection, which is a valuable feature in some applications. The received signal strength indicator (RSSI)
provides a measure of the signal strength received on the tuned channel. The resolution of the RSSI is 0.5 dB. This
high-resolution RSSI enables accurate channel power measurements for clear channel assessment (CCA), carrier
sense (CS), and listen before talk (LBT) functionality. A comprehensive programmable packet handler is integrated
to create a variety of communication topologies ranging from peer-to-peer networks to mesh networks. The
extensive programmability of the packet header allows for advanced packet filtering, which, in turn enables a mix of
broadcast, group, and point-to-point communication. A wireless communication channel can be corrupted by noise
and interference, so it is important to know if the received data is free of errors. A cyclic redundancy check (CRC)
is used to detect the presence of erroneous bits in each packet. A CRC is computed and appended at the end of
each transmitted packet and verified by the receiver to confirm that no errors have occurred. The packet handler
and CRC can significantly reduce the load on the system microcontroller allowing for a simpler and cheaper
microcontroller. The digital modem includes the TX modulator, which converts the TX data bits into the
corresponding stream of digital modulation values to be summed with the fractional input to the sigma-delta
modulator. This modulation approach results in highly accurate resolution of the frequency deviation. A Gaussian
filter is implemented to support GFSK and 4GFSK, considerably reducing the energy in adjacent channels. The
default bandwidth-time product (BT) is 0.5 for all programmed data rates, but it may be adjusted to other values.
5.2.1. Automatic Gain Control (AGC)
The AGC algorithm is implemented digitally using an advanced control loop optimized for fast response time. The
AGC occurs within a single bit or in less than 2 µs. Peak detectors at the output of the LNA and PGA allow for
optimal adjustment of the LNA gain and PGA gain to optimize IM3, selectivity, and sensitivity performance.
5.2.2. Auto Frequency Correction (AFC)
Frequency mistuning caused by crystal inaccuracies can be compensated for by enabling the digital automatic
frequency control (AFC) in receive mode. There are two types of integrated frequency compensation: modem
frequency compensation and AFC by adjusting the PLL frequency. With AFC disabled, the modem compensation
can correct for frequency offsets up to ±0.25 times the IF bandwidth. When the AFC is enabled, the received signal
is centered in the passband of the IF filter, providing optimal sensitivity and selectivity over a wider range of
frequency offsets up to ±0.35 times the IF bandwidth. When AFC is enabled, the preamble length needs to be long
enough to settle the AFC. As shown in Table 13 on page 27, an additional byte of preamble is typically required to
settle the AFC.
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5.2.3. Image Rejection and Calibration
Since the receiver utilizes a low-IF architecture, the selectivity will be affected by the image frequency. The IF
frequency is 468.75 kHz (Fxtal/64), and the image frequency will be at 937.5 kHz (2 x Fxtal/64) below the RF
frequency. The native image rejection of the Si446x family is 40 dB. Image rejection calibration is available in the
Si446x to improve the image rejection to more than 55 dB. The calibration is initiated with the IRCAL API
command. The calibration uses an internal signal source, so no external signal generator is required. The initial
calibration takes 250 ms, and periodic re-calibration takes 100 ms. Recalibration should be initiated when the
temperature has changed more than 30 °C.
5.2.4. Received Signal Strength Indicator
The received signal strength indicator (RSSI) is an estimate of the signal strength in the channel to which the
receiver is tuned. The RSSI measurement is done after the channel filter, so it is only a measurement of the
in-band signal power (desired or undesired). There are two methods for reading the RSSI value and several
different options for configuring the returned RSSI value. The fastest method for reading the RSSI is to configure
one of the four fast response registers (FRR) to return a latched RSSI value. The latched RSSI value is measured
once per packet and is latched at a configurable amount of time after RX mode is entered. The fast response
registers can be read in 16 SPI clock cycles with no requirement to wait for CTS. The RSSI value may also be read
out of the GET_MODEM_STATUS command. In this command, both the current RSSI and the latched RSSI are
available. The current RSSI value represents the signal strength at the instant in time the GET_MODEM_STATUS
command is processed and may be read multiple times per packet. Reading the RSSI in the
GET_MODEM_STATUS command takes longer than reading the RSSI out of the fast response register. After the
initial command, it takes 33 μs for CTS to be set and then the four or five bytes of SPI clock cycles to read out the
respective current or latched RSSI values.
The RSSI configuration options are set in the MODEM_RSSI_CONTROL API property. The latched RSSI value
may be latched and stored based on the following events: preamble detection, sync detection, or a configurable
number of bit times measured after the start of RX mode (minimum of 4 bit times). The requirement for a minimum
of four bit times is determined by the processing delay and settling through the modem and digital channel filter. In
MODEM_RSSI_CONTROL, the RSSI may be defined to update every bit period or to be averaged and updated
every four bit periods. If RSSI averaging over four bits is enabled, the latched RSSI value will be delayed to a
minimum of seven bits after the start of RX mode to allow for the averaging. The latched RSSI values are cleared
when entering RX mode so they may be read after the packet is received or after dropping back to standby mode.
If the RSSI value has been cleared by the start of RX but not yet latched, a value of 0 will be returned if it is
attempted to be read.
The RSSI value read by the API may be translated into dBm by the following linear equation:
RF_Input_Level_dBm = (RSSI_value / 2) – MODEM_RSSI_COMP – 70
The MODEM_RSSI_COMP property provides for fine adjustment of the relationship between the actual RF input
level (in dBm) and the returned RSSI value. That is, adjustment of this property allows the user to shift the RSSI vs
RF Input Power curve up and down. This may be desirable to compensate for differences in front-end insertion loss
between multiple designs (e.g., due to the presence of a SAW preselection filter, or an RF switch). A value of
MODEM_RSSI_COMP = 0x40 = 64d is appropriate for most applications.
Clear channel assessment (CCA) or RSSI threshold detection is also available. An RSSI threshold may be set in
the MODEM_RSSI_THRESH API property. If the Current RSSI value is above this threshold, an interrupt or GPIO
may notify the host. Both the latched version and asynchronous version of this threshold are available on any of
the GPIOs. Automatic fast hopping based on RSSI is available. See “5.3.1.2. Automatic RX Hopping and Hop
Table”.
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5.2.5. RSSI Jump Indicator (Collision Detection)
The chip is capable of detecting a jump in RSSI in either direction (i.e., either a signal increase or a signal
decrease). Both polarities of jump detection may be enabled simultaneously, resulting in detection of a Jump-Up or
Jump-Down event. This may be used to detect whether a secondary interfering signal (desired or undesired) has
“collided” with reception of the current packet. An interrupt flag or GPIO pin may be configured to notify the host
MCU of the Jump event. The change in RSSI level required to trigger the Jump event is programmable through the
MODEM_RSSI_JUMP_THRESH API property.
The chip may be configured to reset the RX state machine upon detection of an RSSI Jump, and thus to
automatically begin reacquisition of the packet. The chip may also be configured to generate an interrupt.
This functionality is intended to detect an abrupt change in RSSI level and to not respond to a slow, gradual change
in RSSI level. This is accomplished by comparing the difference in RSSI level over a programmable time period. In
this fashion, the chip effectively evaluates the slope of the change in RSSI level.
The arrival of a desired packet (i.e., the transition from receiving noise to receiving a valid signal) will likely be
detected as an RSSI Jump event. For this reason, it is recommended to enable this feature in mid-packet (i.e., after
signal qualification, such as PREAMBLE_VALID.) Refer to the API documentation for configuration options.
5.3. Synthesizer
An integrated Sigma Delta () Fractional-N PLL synthesizer capable of operating over the bands from 142–175,
283–350, 350–525, and 850–1050 MHz. Using a  synthesizer has many advantages; it provides flexibility in
choosing data rate, deviation, channel frequency, and channel spacing. The transmit modulation is applied directly
to the loop in the digital domain through the fractional divider, which results in very precise accuracy and control
over the transmit deviation. The frequency resolution in the 850–1050 MHz band is 28.6 Hz with finer resolution in
the other bands. The nominal reference frequency to the PLL is 30 MHz, but any XTAL frequency from 25 to
32 MHz may be used. The modem configuration calculator in WDS will automatically account for the XTAL
frequency being used. The PLL utilizes a differential LC VCO with integrated on-chip inductors. The output of the
VCO is followed by a configurable divider, which will divide the signal down to the desired output frequency band.
5.3.1. Synthesizer Frequency Control
The frequency is set by changing the integer and fractional settings to the synthesizer. The WDS calculator will
automatically provide these settings, but the synthesizer equation is shown below for convenience. The APIs for
setting the frequency are FREQ_CONTROL_INTE, FREQ_CONTROL_FRAC2, FREQ_CONTROL_FRAC1, and
FREQ_CONTROL_FRAC0.
 freq_xo
fc_frac- 2
RF_channel =  fc_inte + ---------------- -----------------------------  Hz 

19 
outdiv
2
Note: The fc_frac/219 value in the above formula has to be a number between 1 and 2.
Table 14. Output Divider (Outdiv) Values for the Si4463/61/60
Outdiv
Lower (MHz)
Upper (MHz)
24
142
175
12
284
350
10
350
420
8
420
525
4
850
1050
Rev 1.0
31
Si4463/61/60-C
5.3.1.1. EZ Frequency Programming
In applications that utilize multiple frequencies or channels, it may not be desirable to write four API registers each
time a frequency change is required. EZ frequency programming is provided so that only a single register write
(channel number) is required to change frequency. A base frequency is first set by first programming the integer
and fractional components of the synthesizer. This base frequency will correspond to channel 0. Next, a channel
step
size
is
programmed
into
the
FREQ_CONTROL_CHANNEL_STEP_SIZE_1
and
FREQ_CONTROL_CHANNEL_STEP_SIZE_0 API registers. The resulting frequency will be:
RF Frequency = Base Frequency + Channel  Stepsi ze
The second argument of the START_RX or START_TX is CHANNEL, which sets the channel number for EZ
frequency programming. For example, if the channel step size is set to 1 MHz, the base frequency is set to
900 MHz with the FREQ_CONTROL_INTE and FREQ_CONTROL_FRAC API properties, and a CHANNEL
number of 5 is programmed during the START_TX command, the resulting frequency will be 905 MHz. If no
CHANNEL argument is written as part of the START_RX/TX command, it will default to the previously-programmed
value. The initial value of CHANNEL is 0; so, if no CHANNEL value is written, it will result in the programmed base
frequency.
5.3.1.2. Automatic RX Hopping and Hop Table
The transceiver supports an automatic RX hopping feature that can be fully configured through the API. This
functionality is useful in applications where it is desired to look for packets but to hop to the next channel if a packet
is not found. The sequence of channel numbers that are visited are specified by entries in a hop table. If this
feature is enabled, the device will automatically start hopping through the channels listed in the hop table as soon
as the chip enters RX mode.
The hop table can hold up to 64 entries and is maintained in firmware inside the RFIC. Each entry is a channel
number, allowing construction of a frequency plan of up to 64 channels. The number of entries in the table is set by
RX HOP TABLE_SIZE API. The specified channels correspond to the EZ frequency programming method for
programming the frequency. The receiver starts at the base channel and hops in sequence from the top of the hop
table to the bottom. The table will wrap around to the base channel once it reaches the end of the table. An entry of
0xFF in the table indicates that the entry should be skipped. The device will hop to the next entry in the table that
contains a non-0xFF value.
There are three conditions that can be used to determine whether to continue hopping or to stay on a particular
channel. These conditions are as follows:
RSSI
threshold
Preamble timeout (invalid preamble pattern)
Sync word timeout (invalid or no sync word detected after preamble)
These conditions can be used individually, or they can be enabled all together by configuring the
RX_HOP_CONTROL API. However, the firmware will make a decision on whether or not to hop based on the first
condition that is met.
The RSSI that is monitored is the current RSSI value. This is compared to the threshold value set in the
MODEM_RSSI_THRESH API property, and, if it is above the threshold value, it will stay on the channel. If the
RSSI is below the threshold, it will continue hopping. There is no averaging of RSSI done during the automatic
hopping from channel to channel. Since the preamble timeout and the sync word timeout are features that require
packet handling, the RSSI threshold is the only condition that can be used if the user is in “direct” or “RAW” mode
where packet handling features are not used.
The RSSI threshold value may be converted to an approximate equivalent RF input power level through the
equation shown in "5.2.4. Received Signal Strength Indicator" on page 30. However, performance should be
verified on the bench to optimize the threshold setting for a given application.
The time spent in receive mode will be determined by the configuration of the hop conditions. Manual RX hopping
will have the fastest turn-around time but will require more overhead and management by the host MCU.
32
Rev 1.0
Si4463/61/60-C
The following are example steps for using Auto Hop:
1. Set the base frequency (inte + frac) and channel step size.
2. Define the number of entries in the hop table (RX_HOP_TABLE_SIZE).
3. Write the channels to the hop table (RX_HOP_TABLE_ENTRY_n)
4. Configure the hop condition and enable auto hopping- RSSI, preamble, or sync (RX_HOP_CONTROL).
5. Set preamble and sync parameters if enabled.
6. Program the RSSI threshold property in the modem using “MODEM_RSSI_THRESH”.
7. Set the preamble threshold using “PREAMBLE_CONFIG_STD_1”.
8. Program the preamble timeout property using “PREAMBLE_CONFIG_STD_2”.
9. Set the sync detection parameters if enabled.
10. If needed, use “GPIO_PIN_CFG” to configure a GPIO to toggle on hop and hop table wrap.
11. Use the “START_RX” API with channel number set to the first valid entry in the hop table (i.e., the first non
0xFF entry).
12. Device should now be in auto hop mode.
5.3.1.3. Manual RX Hopping
The RX_HOP command provides the fastest method for hopping from RX to RX but it requires more overhead and
management by the host MCU. The timing is faster with this method than Start_RX or RX hopping because one of
the calculations required for the synthesizer calibrations is offloaded to the host and must be calculated/stored by
the host, VCO_CNT0. For VCO_CNT values, download the Si446x RX_HOP PLL calculator spreadsheet from the
Si446x product website.
5.4. Transmitter (TX)
The Si4463 contains an integrated +20 dBm transmitter or power amplifier that is capable of transmitting from –20
to +20 dBm. The resolution of the programmable steps in output power is less than 0.25 dB when operated within
6 dB of the maximum power setting; the resolution of the steps in output power becomes coarser and more
non-linear as the output power is reduced towards the minimum end of its control range. The Si4463 PA is
designed to provide the highest efficiency and lowest current consumption possible. The Si4460 is designed to
supply +10 dBm output power for less than 20 mA for applications that require operation from a single coin cell
battery. The Si4460 can operate with Class-E matching and output up to +13 dBm Tx power at a supply voltage of
VDD = 3.3 V. All PA options are single-ended to allow for easy antenna matching and low BOM cost. Automatic
ramp-up and ramp-down is automatically performed to reduce unwanted spectral spreading. Refer to “AN627:
Si4460/61 Low-Power PA Matching” and “AN648: PA Matching” for details on TX matching options.
The chip’s TXRAMP pin is disabled by default to save current in cases where the on-chip PA provides sufficient
output power to drive the antenna. In cases where on-chip PA will drive the external PA, and the external PA needs
a ramping signal, TXRAMP is the signal to use. To enable TXRAMP, set the API Property PA_MODE[7] = 1.
TXRAMP will start to ramp up, and ramp down at the SAME time as the internal on-chip PA ramps up/down.
However, the time constant of the TXRAMP signal for the external PA is programmed independently of the ramp
time constant for the on-chip PA. The ramp time constant for TXRAMP is programmed by the TC[3:0] field in the
PA_RAMP_EX API property and provides the following approximate ramp times as a function of TC[3:0] value.
Rev 1.0
33
Si4463/61/60-C
Table 15. Ramp Times as a Function of TC[3:0] Value
TC
Ramp Time (µs)
0
1.25
1
1.33
2
1.43
3
1.54
4
1.67
5
1.82
6
2.00
7
2.22
8
2.50
9
2.86
10
3.33
11
4.00
12
5.00
13
6.67
14
10.00
15
20.00
The ramping profile is close to a linear ramping profile with smoothed out corner when approaching Vhi and Vlo.
The TXRAMP pin can source up to 1 mA without voltage drooping. The TXRAMP pin’s sinking capability is
equivalent to a 10 k pull-down resistor.
Vhi = 3 V when Vdd > 3.3 V. When Vdd < 3.3 V, the Vhi will be closely following the Vdd, and ramping time will be
smaller also.
Vlo = 0 V when NO current needed to be sunk into TXRAMP pin. If 10uA need to be sunk into the chip, Vlo will be
10 µA x 10k = 100 mV.
34
Number
Command
Summary
0x2200
PA_MODE
0x2201
PA_PWR_LVL
0x2202
PA_BIAS_CLKDUTY
Adjust TX power in coarse steps
and optimizes for different
match configurations.
0x2203
PA_TC
Changes the ramp up/down time
of the PA.
Sets PA type.
Adjust TX power in fine steps.
Rev 1.0
Si4463/61/60-C
5.4.1. Si4463: +20 dBm PA
The +20 dBm configuration utilizes a class-E matching configuration for all frequency bands except 169 MHz
where it uses a Square Wave match. Typical performance for the 915 MHz band for output power steps, voltage,
and temperature are shown in Figures 10–12. The output power is changed in 128 steps through PA_PWR_LVL
API. For detailed matching values, BOM, and performance at other frequencies, refer to “AN648: PA Matching”.
TXPowervs.PA_PWR_LVL
25
20
15
10
5
Ͳ5
Ͳ10
Ͳ15
Ͳ20
Ͳ25
Ͳ30
Ͳ35
Ͳ40
0
20
40
60
80
100
120
PA_PWR_LVL
Figure 10. +20 dBm TX Power vs. PA_PWR_LVL
TX Power vs. VDD
22
TX Power (dBm)
TXPower(dBm)
0
20
18
16
14
12
10
1.8
2
2.2
2.4
2.6
2.8
3
3.2
3.4
3.6
Supply Voltage (VDD)
Figure 11. +20 dBm TX Power vs. VDD
Rev 1.0
35
Si4463/61/60-C
TX Power vs Temp
TX Power (dBm)
20.5
20
19.5
19
18.5
18
-40 -30 -20 -10
0
10
20
30
40
50
60
70
80
Temperature (C)
Figure 12. +20 dBm TX Power vs. Temp
5.5. Crystal Oscillator
The Si446x includes an integrated crystal oscillator with a fast start-up time of less than 250 µs. The design is
differential with the required crystal load capacitance integrated on-chip to minimize the number of external
components. By default, all that is required off-chip is the crystal. The default crystal is 30 MHz, but the circuit is
designed to handle any XTAL from 25 to 32 MHz. If a crystal different than 30 MHz is used, the POWER_UP API
boot command must be modified. The WDS calculator crystal frequency field must also be changed to reflect the
frequency being used. The crystal load capacitance can be digitally programmed to accommodate crystals with
various load capacitance requirements and to adjust the frequency of the crystal oscillator. The tuning of the crystal
load capacitance is programmed through the GLOBAL_XO_TUNE API property. The total internal capacitance is
11 pF and is adjustable in 127 steps (70 fF/step). The crystal frequency adjustment can be used to compensate for
crystal production tolerances. The frequency offset characteristics of the capacitor bank are demonstrated in
Figure 13.
Figure 13. Capacitor Bank Frequency Offset Characteristics
36
Rev 1.0
Si4463/61/60-C
Utilizing the on-chip temperature sensor and suitable control software, the temperature dependency of the crystal
can be canceled.
A TCXO or external signal source can easily be used in place of a conventional XTAL and should be connected to
the XIN pin. The incoming clock signal is recommended to have a peak-to-peak swing in the range of 600 mV to
1.4 V and ac-coupled to the XIN pin. If the peak-to-peak swing of the TCXO exceeds 1.4 V peak-to-peak, then dc
coupling to the XIN pin should be used. The maximum allowed swing on XIN is 1.8 V peak-to-peak.
The XO capacitor bank should be set to 0 whenever an external drive is used on the XIN pin. In addition, the
POWER_UP command should be invoked with the TCXO option whenever external drive is used.
Rev 1.0
37
Si4463/61/60-C
6. Data Handling and Packet Handler
6.1. RX and TX FIFOs
Two 64-byte FIFOs are integrated into the chip, one for RX and one for TX, as shown in Figure 14. For dedicated
TX or RX, the FIFO size is up to 129 bytes. Writing to command Register 66h loads data into the TX FIFO, and
reading from command Register 77h reads data from the RX FIFO. The TX FIFO has a threshold for when the
FIFO is almost empty, which is set by the “TX_FIFO_EMPTY” property. An interrupt event occurs when the data in
the TX FIFO reaches the almost empty threshold. If more data is not loaded into the FIFO, the chip automatically
exits the TX state after the PACKET_SENT interrupt occurs. The RX FIFO has one programmable threshold, which
is programmed by setting the “RX_FIFO_FULL” property. When the incoming RX data crosses the Almost Full
Threshold, an interrupt will be generated to the microcontroller via the nIRQ pin. The microcontroller will then need
to read the data from the RX FIFO. The RX Almost Full Threshold indication implies that the host can read at least
the threshold number of bytes from the RX FIFO at that time. Both the TX and RX FIFOs may be cleared or reset
with the “FIFO_RESET” command.
RX FIFO
TX FIFO
RX FIFO Almost
Full Threshold
TX FIFO Almost
Empty Threshold
Figure 14. TX and RX FIFOs
6.2. Packet Handler
Config
0, 2, o r 4
Bytes
Con fig
0, 2, o r 4
Bytes
Rev 1.0
0, 2, o r 4
B ytes
C RC Field 5 (op t)
Field 5 (opt)
Data
C RC Field 4 (op t)
Con fig
Figure 15. Packet Handler Structure
38
Field 4 (opt)
Data
C RC Field 3 (op t)
Field 3 (opt)
Data
Con fig
C RC Field 2 (op t)
1-4 Bytes
F ield 2 (o pt)
Pkt Len gth or Data
Field 1
Header or Data
1-255 Bytes
C RC Field 1 (op t)
Preamble
Sync Word
When using the FIFOs, automatic packet handling may be enabled for TX mode, RX mode, or both. The usual
fields for network communication, such as preamble, synchronization word, headers, packet length, and CRC, can
be configured to be automatically added to the data payload. The fields needed for packet generation normally
change infrequently and can therefore be stored in registers. Automatically adding these fields to the data payload
in TX mode and automatically checking them in RX mode greatly reduces the amount of communication between
the microcontroller and Si446x. It also greatly reduces the required computational power of the microcontroller. The
general packet structure is shown in Figure 15. Any or all of the fields can be enabled and checked by the internal
packet handler.
Con fig
0, 2, or 4
Bytes
0, 2, or 4
Bytes
Si4463/61/60-C
The fields are highly programmable and can be used to check any kind of pattern in a packet structure. The
general functions of the packet handler include the following:
Detection/validation
of Preamble quality in RX mode (PREAMBLE_VALID signal)
of Sync word in RX mode (SYNC_OK signal)
Detection of valid packets in RX mode (PKT_VALID signal)
Detection of CRC errors in RX mode (CRC_ERR signal)
Data de-whitening and/or Manchester decoding (if enabled) in RX mode
Match/Header checking in RX mode
Storage of Data Field bytes into FIFO memory in RX mode
Construction of Preamble field in TX mode
Construction of Sync field in TX mode
Construction of Data Field from FIFO memory in TX mode
Construction of CRC field (if enabled) in TX mode
Data whitening and/or Manchester encoding (if enabled) in TX mode
For details on how to configure the packet handler, see “AN626: Packet Handler Operation for Si446x RFICs”.
Detection
Rev 1.0
39
Si4463/61/60-C
7. RX Modem Configuration
The Si446x can easily be configured for different data rate, deviation, frequency, etc. by using the Radio
Configuration Application (RCA) GUI which is part of the Wireless Development Suite (WDS) program.
8. Auxiliary Blocks
8.1. Wake-up Timer and 32 kHz Clock Source
The chip contains an integrated wake-up timer that can be used to periodically wake the chip from sleep mode. The
wake-up timer runs from either the internal 32 kHz RC Oscillator, or from an external 32 kHz XTAL.
The wake-up timer can be configured to run when in sleep mode. If WUT_EN = 1 in the GLOBAL_WUT_CONFIG
property, prior to entering sleep mode, the wake-up timer will count for a time specified defined by the
GLOBAL_WUT_R and GLOBAL_WUT_M properties. At the expiration of this period, an interrupt will be generated
on the nIRQ pin if this interrupt is enabled in the INT_CTL_CHIP_ENABLE property. The microcontroller will then
need to verify the interrupt by reading the chip interrupt status either via GET_INT_STATUS or a fast response
register. The formula for calculating the Wake-Up Period is as follows:
WUT_R
42
WUT = WUT_M  -----------------------------  ms 
32.768
The RC oscillator frequency will change with temperature; so, a periodic recalibration is required. The RC oscillator
is automatically calibrated during the POWER_UP command and exits from the Shutdown state. To enable the
recalibration feature, CAL_EN must be set in the GLOBAL_WUT_CONFIG property, and the desired calibration
period should be selected via WUT_CAL_PERIOD[2:0] in the same API property. During the calibration, the 32
kHz RC oscillator frequency is compared to the 30 MHz XTAL and then adjusted accordingly. The calibration needs
to start the 30 MHz XTAL, which increases the average current consumption; so, a longer CAL_PERIOD results in
a lower average current consumption. The 32 kHz XTAL accuracy is comprised of both the XTAL parameters and
the internal circuit. The XTAL accuracy can be defined as the XTAL initial error + XTAL aging + XTAL temperature
drift + detuning from the internal oscillator circuit. The error caused by the internal circuit is typically less than
10 ppm. Refer to API documentation for details on WUT related commands and properties.
8.2. Low Duty Cycle Mode (Auto RX Wake-Up)
The low duty cycle (LDC) mode is implemented to automatically wake-up the receiver to check if a valid signal is
available or to enable the transmitter to send a packet. It allows low average current polling operation by the Si446x
for which the wake-up timer (WUT) is used. RX and TX LDC operation must be set via the
GLOBAL_WUT_CONFIG property when setting up the WUT. The LDC wake-up period is determined by the
following formula:
WUT_R
42
LDC = WUT_LDC  -----------------------------  ms 
32.768
where the WUT_LDC parameter can be set by the GLOBAL_WUT_LDC property. The WUT period must be set in
conjunction with the LDC mode duration; for the relevant API properties, see the wake-up timer (WUT) section.
40
Rev 1.0
Si4463/61/60-C
Figure 16. RX and TX LDC Sequences
The basic operation of RX LDC mode is shown in Figure 17. The receiver periodically wakes itself up to work on
RX_STATE during LDC mode duration. If a valid preamble is not detected, a receive error is detected, or an entire
packet is not received, the receiver returns to the WUT state (i.e., ready or sleep) at the end of LDC mode duration
and remains in that mode until the beginning of the next wake-up period. If a valid preamble or sync word is
detected, the receiver delays the LDC mode duration to receive the entire packet. If a packet is not received during
two LDC mode durations, the receiver returns to the WUT state at the last LDC mode duration until the beginning
of the next wake-up period.
Figure 17. Low Duty Cycle Mode for RX
In TX LDC mode, the transmitter periodically wakes itself up to transmit a packet that is in the data buffer. If a
packet has been transmitted, nIRQ goes low if the option is set in the INT_CTL_ENABLE property. After
transmitting, the transmitter immediately returns to the WUT state and stays there until the next wake-up time
expires.
8.3. Temperature, Battery Voltage, and Auxiliary ADC
The Si446x family contains an integrated auxiliary ADC for measuring internal battery voltage, an internal
temperature sensor, or an external component over a GPIO. The ADC utilizes a SAR architecture and achieves
11-bit resolution. The Effective Number of Bits (ENOB) is 9 bits. When measuring external components, the input
voltage range is 1 V, and the conversion rate is between 300 Hz to 2.44 kHz. The ADC value is read by first
sending the GET_ADC_READING command and enabling the inputs that are desired to be read: GPIO, battery, or
temp. The temperature sensor accuracy at 25 °C is typically ±2 °C. Refer to API documentation for details on the
command and reply stream.
8.4. Low Battery Detector
The low battery detector (LBD) is enabled and utilized as part of the wake-up-timer (WUT). The LBD function is not
available unless the WUT is enabled, but the host MCU can manually check the battery voltage anytime with the
auxiliary ADC. The LBD function is enabled in the GLOBAL_WUT_CONFIG API property. The battery voltage will
be compared against the threshold each time the WUT expires. The threshold for the LBD function is set in
GLOBAL_LOW_BATT_THRESH. The threshold steps are in increments of 50 mV, ranging from a minimum of
1.5 V up to 3.05 V. The accuracy of the LBD is ±3%. The LBD notification can be configured as an interrupt on the
nIRQ pin or enabled as a direct function on one of the GPIOs.
Rev 1.0
41
Si4463/61/60-C
8.5. Antenna Diversity
To mitigate the problem of frequency-selective fading due to multipath propagation, some transceiver systems use
a scheme known as antenna diversity. In this scheme, two antennas are used. Each time the transceiver enters RX
mode the receive signal strength from each antenna is evaluated. This evaluation process takes place during the
preamble portion of the packet. The antenna with the strongest received signal is then used for the remainder of
that RX packet. The same antenna will also be used for the next corresponding TX packet. This chip fully supports
antenna diversity with an integrated antenna diversity control algorithm. The required signals needed to control an
external SPDT RF switch (such as a PIN diode or GaAs switch) are available on the GPIOx pins. The operation of
these GPIO signals is programmable to allow for different antenna diversity architectures and configurations. The
antdiv[2:0] bits are found in the MODEM_ANT_DIV_CONTROL API property descriptions and enable the antenna
diversity mode. The GPIO pins are capable of sourcing up to 5 mA of current; so, it may be used directly to
forward-bias a PIN diode if desired. The antenna diversity algorithm will automatically toggle back and forth
between the antennas until the packet starts to arrive. The recommended preamble length for optimal antenna
selection is 8 bytes.
8.6. Preamble Sense Mode
This mode of operation is suitable for extremely low power applications where power consumption is important.
The preamble sense mode (PSM) takes advantage of the Digital Signal Arrival detector (DSA), which can detect a
preamble within eight bit times with no sensitivity degradation. This fast detection of an incoming signal can be
combined with duty cycling of the receiver during the time the device is searching or sniffing for packets over the
air. The average receive current is lowered significantly when using this mode. In applications where the timing of
the incoming signal is unknown, the amount of power savings is primarily dependent on the data rate and preamble
length as the Rx inactive time is determined by these factors. In applications where the sleep time is fixed and the
timing of the incoming signal is known, the average current also depends on the sleep time. The PSM mode is
similar to the low duty cycle mode but has the benefit of faster signal detection and autonomous duty cycling of the
receiver to achieve even lower average receive currents. This mode can be used with the low power mode (LP)
which has an active RX current of 10 mA or with the high-performance (HP) mode which has an active RX current
of 13 mA.
Figure 18. Preamble Sense Mode
Table 16. Data Rates
Data Rate
1.2 kbps
9.6 kbps
50 kbps
100 kbps
PM length = 4 bytes
6.48
6.84
8.44
10.43
mA
PM length = 8 bytes
3.83
3.96
4.57
5.33
mA
Note: Typical values. Active RX current is 13 mA.
42
Rev 1.0
Si4463/61/60-C
9. Wireless MBUS support
Wireless MBus is a widely accepted standard for smart meter communication in Europe. The radio supports all
WMBus modes per the latest draft specification of the EN13757-4 standard. This includes a much wider deviation
error tolerance of ±30% and frequency error tolerance of ±4 kHz, short preamble support (16-bit preamble for 2
and 4 level FSK modes), 3-of-6 encoding and decoding and 169 MHz N modes including N2g.
In addition, Silicon Labs has a production ready WMBus stack available at no additional cost which supports all
modes and runs on the EFM32 (32-bit ARM) family of energy friendly microcontrollers. This stack and complete
documentation including PHY configuration and test results are available for download from the EZRadioPRO
page on the Silicon Labs website.
10. ETSI EN300 220 Category 1
The radio is capable of supporting ETSI Category 1 applications (social alarms, healthcare applications, etc.) in the
169 MHz and 868 MHz bands. Blocking performance is improved at the 2 MHz and 10 MHz offsets allowing for
additional margin from the regulatory limits. The radio complies with ACS limits at the 25 kHz offset in both,
169 MHz and 868 MHz bands. In the 169 MHz band, there is no need for an external SAW filter for 2 MHz and
10 MHz blocking resulting in a lower system cost. In the 868 MHz band, an external SAW filter is still required to
meet the Cat 1 blocking limits. An RF Pico board is available for evaluation specifically for ETSI Cat 1 applications.
Test conditions for ETSI Cat 1 specifications are different from the typical conditions and are stated below.
Data Rate: 3 kbps
Deviation: 2 kHz
Modulation: 2 GFSK
IF mode: Fixed and/or Scaled IF
RX bandwidth: 13 kHz
BER target: 0.1%
Blocker signal: CW
ETSI Cat 1 limits
169 MHz band
(no SAW)
868 MHz band
(no SAW)
±25 kHz ACS
54 dB
62 dB
58 dB
±2 MHz blocking
84 dB
88 dB
76 dB
±10 MHz blocking
84 dB
90 dB
82 dB
RX sensitivity
–107 dB
–108 dB
–108 dB
Spurious response
35 dB
40 dB
40 dB
For further details on configuring the radio for ETSI Cat 1 applications, refer to the application notes available on
the Silicon Labs website.
Rev 1.0
43
Si4463/61/60-C
SDN
1
XOUT
XIN
GND
GPIO2
GPIO3
11. Pin Descriptions: Si4463/61/60
20 19 18 17 16
RXp 2
15 nSEL
RXn 3
14 SDI
GND
PAD
TX 4
13 SDO
Pin
Pin Name
7
8
9
VDD
GPIO0
10 11 nIRQ
GPIO1
6
TXRamp
12 SCLK
VDD
NC 5
I/0
Description
1
SDN
I
Shutdown Input Pin.
0–VDD V digital input. SDN should be = 0 in all modes except Shutdown mode.
When SDN = 1, the chip will be completely shut down, and the contents of the
registers will be lost.
2
RXp
I
Differential RF Input Pins of the LNA.
3
RXn
I
See application schematic for example matching network.
4
TX
O
5
NC
6
VDD
VDD
7
TXRAMP
O
8
VDD
VDD
9
GPIO0
I/O
General Purpose Digital I/O.
I/O
May be configured through the registers to perform various functions including:
Microcontroller Clock Output, FIFO status, POR, Wake-Up timer, Low Battery
Detect, TRSW, AntDiversity control, etc.
Transmit Output Pin.
10
GPIO1
The PA output is an open-drain connection, so the L-C match must supply
VDD (+3.3 VDC nominal) to this pin.
It is recommended to connect this pin to GND per the reference design schematic. Not connected internally to any circuitry.
+1.8 to +3.8 V Supply Voltage Input to Internal Regulators.
The recommended VDD supply voltage is +3.3 V.
Programmable Bias Output with Ramp Capability for External FET PA.
See "5.4. Transmitter (TX)" on page 33.
+1.8 to +3.8 V Supply Voltage Input to Internal Regulators.
The recommended VDD supply voltage is +3.3 V.
General Microcontroller Interrupt Status Output.
11
44
nIRQ
O
When the Si4463/61 exhibits any one of the interrupt events, the nIRQ pin will
be set low = 0. The Microcontroller can then determine the state of the interrupt by reading the interrupt status. No external resistor pull-up is required, but
it may be desirable if multiple interrupt lines are connected.
Rev 1.0
Si4463/61/60-C
Pin
Pin Name
I/0
Description
Serial Clock Input.
12
SCLK
I
13
SDO
O
0–VDD V digital input. This pin provides the serial data clock function for the
4-line serial data bus. Data is clocked into the Si4463/61 on positive edge transitions.
0–VDD V Digital Output.
Provides a serial readback function of the internal control registers.
Serial Data Input.
14
SDI
I
0–VDD V digital input. This pin provides the serial data stream for the 4-line
serial data bus.
Serial Interface Select Input.
15
nSEL
I
0–VDD V digital input. This pin provides the Select/Enable function for the
4-line serial data bus.
Crystal Oscillator Output.
16
XOUT
O
17
XIN
I
Connect to an external 25 to 32 MHz crystal, or leave floating when driving
with an external source on XIN.
Crystal Oscillator Input.
Connect to an external 25 to 32 MHz crystal, or connect to an external source.
When using an XTAL, leave floating per the reference design schematic. When
using a TCXO, connect to TCXO GND, which should be separate from the
board’s reference ground plane.
18
GND
GND
19
GPIO2
I/O
General Purpose Digital I/O.
20
GPIO3
I/O
May be configured through the registers to perform various functions, including
Microcontroller Clock Output, FIFO status, POR, Wake-Up timer, Low Battery
Detect, TRSW, AntDiversity control, etc.
GND
The exposed metal paddle on the bottom of the Si446x supplies the RF and circuit ground(s) for the entire chip. It is very important that a good solder connection is made between this exposed metal paddle and the ground plane of the
PCB underlying the Si446x.
PKG
PADDLE_GND
Rev 1.0
45
Si4463/61/60-C
12. Ordering Information
Part Number
Si4463-C2A-GM
Si4461-C2A-GM
Si4460-C2A-GM
Description
Package Type
Operating
Temperature
ISM EZRadioPRO Transceiver
QFNPb-free
–40 to +85 °C
ISM EZRadioPRO Transceiver
QFNPb-free
–40 to +85 °C
ISM EZRadioPRO Transceiver
QFNPb-free
–40 to +85 °C
Note: Add an “(R)” at the end of the device part number to denote tape and reel option.
46
Rev 1.0
Si4463/61/60-C
13. Package Outline: Si4463/61/60
Figure 19 illustrates the package details for the Si446x. Table 17 lists the values for the dimensions shown in the
illustration.
2X
bbb C
B
A
D
D2
Pin 1 (Laser)
e
20
20x L
1
E
E2
2X
aaa C
A1
20x b
ccc C
ddd
C A B
eee C
A
SEATING PLANE
A3
C
Figure 19. 20-Pin Quad Flat No-Lead (QFN)
Rev 1.0
47
Si4463/61/60-C
Table 17. Package Dimensions
Dimension
Min
Nom
Max
A
0.80
0.85
0.90
A1
0.00
0.02
0.05
A3
b
0.20 REF
0.18
0.25
D
D2
0.30
4.00 BSC
2.45
2.60
e
0.50 BSC
E
4.00 BSC
2.75
E2
2.45
2.60
2.75
L
0.30
0.40
0.50
aaa
0.15
bbb
0.15
ccc
0.10
ddd
0.10
eee
0.08
Notes:
1. All dimensions are shown in millimeters (mm) unless otherwise noted.
2. Dimensioning and tolerancing per ANSI Y14.5M-1994.
3. This drawing conforms to the JEDEC Solid State Outline MO-220,
Variation VGGD-8.
4. Recommended card reflow profile is per the JEDEC/IPC J-STD-020
specification for Small Body Components.
48
Rev 1.0
Si4463/61/60-C
14. PCB Land Pattern: Si4463/61/60
Figure 20 illustrates the PCB land pattern details for the Si446x. Table 18 lists the values for the dimensions shown
in the illustration.
Figure 20. PCB Land Pattern
Rev 1.0
49
Si4463/61/60-C
Table 18. PCB Land Pattern Dimensions
Symbol
Millimeters
Min
Max
C1
3.90
4.00
C2
3.90
4.00
E
0.50 REF
X1
0.20
0.30
X2
2.55
2.65
Y1
0.65
0.75
Y2
2.55
2.65
Notes:
General
1. All dimensions shown are in millimeters (mm) unless otherwise noted.
2. This land pattern design is based on IPC-7351 guidelines.
Solder Mask Design
3. All metal pads are to be non-solder mask defined (NSMD). Clearance
between the solder mask and the metal pad is to be 60 µm minimum, all
the way around the pad.
Stencil Design
4. A stainless steel, laser-cut and electro-polished stencil with trapezoidal
walls should be used to assure good solder paste release.
5. The stencil thickness should be 0.125 mm (5 mils).
6. The ratio of stencil aperture to land pad size should be 1:1 for the
perimeter pads.
7. A 2x2 array of 1.10 x 1.10 mm openings on 1.30 mm pitch should be
used for the center ground pad.
Card Assembly
8. A No-Clean, Type-3 solder paste is recommended.
9. The recommended card reflow profile is per the JEDEC/IPC J-STD-020
specification for small body components.
50
Rev 1.0
Si4463/61/60-C
15. Top Marking
15.1. Si4463/61/60 Top Marking
15.2. Top Marking Explanation
Mark Method
YAG Laser
Line 1 Marking
Part Number
44632A = Si4463 Rev 2A1
44612A = Si4461 Rev 2A1
44602A = Si4460 Rev 2A1
Line 2 Marking
TTTTTT = Internal Code
Internal tracking code.2
Line 3 Marking
YY = Year
WW = Workweek
Assigned by the Assembly House. Corresponds to the last
significant digit of the year and workweek of the mold date.
Notes:
1. The first letter after the part number is part of the ROM revision. The last letter indicates the firmware
revision.
2. The first letter of this line is part of the ROM revision.
Rev 1.0
51
Si4463/61/60-C
DOCUMENT CHANGE LIST
Revision 0.1 to Revision 0.2






Corrected minor typos in text descriptions.
Updated several parameters in the Electrical Spec
Tables.
Updated sections 4, 5 and 8.6 for better description
of Modem and Hardware configuration options,
Internal Functional Blocks and Preamble Sense
Mode.
Updated Table 9, “Serial Interface Timing
Parameters,” on page 16.
Updated "12. Ordering Information" on page 46.
Updated "15. Top Marking" on page 51.
Revision 0.2 to Revision 1.0
Updated parameters in “1. Electrical Specifications”.
 Minor updates to text descriptions.
 Updated Table 15.
 Updated “11. Pin Descriptions: Si4463/61/60”.

52
Rev 1.0
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